ALTERNATIVE FORMULATIONS AND PACKAGING TO REDUCE USE OF
CHLOROFLUOROCARBONS (CFCs)
Thomas P. Nelson and Sharon L. Wev...
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ALTERNATIVE FORMULATIONS AND PACKAGING TO REDUCE USE OF
CHLOROFLUOROCARBONS (CFCs)
Thomas P. Nelson and Sharon L. Wevill Radian Corporation Austin, Texas
NOYES DATA CORPORATION Park Ridge, New Jersey, U.S.A.
Copyright @ 1990 by Noyes Data Corporation Library of Congress Catalog Card Number: 90-7746 ISBN: 0-8155-1257-0 ISSN: 0090-516X Printed i n the United States Published in the United States of America b y Noyes Data Corporation Mill Road, Park Ridge, New Jersay 07656 10987654321
Library of Congress Cataloging-in-Publication Data Nelson, T.P. Alternative formulations and packaging t o reduce use o f chlorofluorocarbons (CFCs) / by Thomas P. Nelson and Sharon L. Wevill. cm. (Pollution technology review, ISSN 0090-516X ;no. p. 194) Includes bibliographical references and index. ISBN 0-8155-1257-0 : 1. Pressure packaging. 2. Aerosol propellants. 3.Chlorofluorocarbons. I.Wevill, Sharon L. II. Title. I II.Series. 1990 TS198 .P7MN45 688.8-7dc20 90-7746 CIP
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Foreword
This book describes alternative formulations and packaging techniques for the reduction or elimination of chlorofluorocarbon (CFC) use as an aerosol propellant. Use of CFCs in specific categories of aerosols considered "nonessential" was banned by the U.S. in 1978. Recent renewed interest in further reducing worldwide production and consumption of CFCs, and other chemicals implicated in the depletion of the earth's stratospheric ozone layer, i s responsible for this study, which covers currently exempted and excluded CFC aerosol applications and their alternatives. The book i s presented in two parts. Part I gives background information on the issue and an overview of technically feasible methods for reducing CFCs in aerosol products without adverse effects on human life and health, military preparedness, and the economy. Part II discusses industry's experience in converting to alternative formulations. Detailed non-CFC formulations are provided for 28 categories of aerosol products. Special equipment may be needed to include these formulations in aerosol containers, and this i s discussed along with a variety of alternative dispensing devices. Advantages and drawbacks of these devices are discussed in detail, and examples of consumer products which have successfully utilized these alternatives are given. The information in the book i s from Alternative Formulations to Reduce CFC Use in U.S. Exempted and Excluded Aerosol Products, prepared by Thomas P. Nelson and Sharon L. Wevill of Radian Corporation for the U.S. Environmental Protection Agency, November 1989. Aerosol Industry Success in Reducing CFC Propellant Usage, prepared by Thomas P. Nelson and Sharon L. Wevill of Radian Corporation for the U.S. Environmental Protection Agency, November 1989. V
vi
Foreword
The table of contents i s organized in such a way as to serve as a subject index and provides easy access to the information contained in the book. Advanced composition and production methods developed by Noyes Data Corporation are employed to bring this durably bound book to you in a minimum of time. Special techniques are used to close the gap between "manuscript" and "completed book." I n order to keep the price of the book to a reasonable level, it has been partially reproduced by photo-offset directly from the original reports and the cost saving passed on to the reader. Due to this method of publishing, certain portions of the book may be less legible than desired.
NOTICE The materials in this book were prepared as accounts of work sponsored by the U.S. Environmental Protection Agency. They have been approved for publication as EPA documents. On this basis the Publisher assumes no responsibility nor liability for errors or any consequences arising from the use of the information contained herein. Mention of trade names or commercial products does not constitute endorsement or recommendation for use by the Agency or the Publisher. Final determination of the suitability of any information or procedure for use contemplated by any user, and the manner of that use, i s the sole responsibility of the user. The reader i s warned that caution must always be exercised when dealing with materials which might be hazardous, such as chlorofluorocarbons and their alternatives, and expert advice should be sought at all times. All information pertaining to law and regulations i s provided for background only. The reader must contact the appropriate legal sources and regulatory authorities for upto-date regulatory requirements, and their interpretation and implementation.
Contents and Subject Index
PART I BACKGROUND AND OVERVIEW
.
1 INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Historical Perspective . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Montreal Protocol Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . . Objectives and Organization of the Report . . . . . . . . . . . . . . . . . . . . .
.
2 2 3 4
2 CFC AEROSOL APPLICATIONS EXEMPTED IN THE U.S . . . . . . . . . . . . 6 Rationale for Exempted Uses of CFC Aerosols . . . . . . . . . . . . . . . . . .9 Release Agents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Lubricants. Cleaner.Solvents. Dusters and/or Coatings for 10 Electronics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Mercaptan (Thiol) Stench-TypeWarning Devices . . . . . . . . . . . . . . 11 Other Warning Devices . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 12 Flying Insect Pesticides. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Metered-Dose Inhalant Drugs (Steroids. Ergotamine Tartrate and Adrenergic Bronchodilator Types) . . . . . . . . . . . . . . . . . . . . 14 Contraceptive Vaginal Foams. . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Hair Restorers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16 Aerosols for Aircraft (Maintenance and Operation) . . . . . . . . . . . .16 Military Aerosols (For Continuing Military Preparedness) . . . . . . . . 17 Diamond Grit Sprays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 CFC-115 for Puffed Food Product Aeration . . . . . . . . . . . . . . . . .18 Rationale for Excluded Uses of CFC Aerosols . . . . . . . . . . . . . . . . . . 20 Drain Openers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 Microscope Slide Cleaners . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 Chewing Gum Removers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21 21 Boat Horns. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . vii
viii
Contents and Subject Index Halon-Type Fire Extinguishers . . . . . . . . . . . . . . . . . . . . . . . . . . 22 Intruder Alarm Devices (for Cars. Trucks. and Homes) . . . . . . . . . .22 Skin Chillers (for Medical Purposes) . . . . . . . . . . . . . . . . . . . . . . 23 Polyurethane Blowing Agent . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 24 Tire Inflators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Foams. Whips and Puffs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 Medical Solvents (Bandage Adhesive and Adhesive Remover) . . . . . . 25 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
3. CURRENT U.S. CONSUMPTION OF CFCs . . . . . . . . . . . . . . . . . . . . .
27 27 Discussion of the Data . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Source of the Data. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 Development of Numbers by Exact Product Type . . . . . . . . . . . . .33 33 Flying Insect Sprays. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Aerosols for Military Use . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34 Metered Dose Inhalant Drugs. . . . . . . . . . . . . . . . . . . . . . . . . . . Conversion of Pounds of CFCs Consumed to Aerosol Units Sold . . . 35 U.S. Marketers and Fillers of CFC Products . . . . . . . . . . . . . . . . . . .36
4. SUGGESTED ALTERNATIVE FORMULATIONS FOR EXEMPTED AND EXCLUDED CFC AEROSOLS . . . . . . . . . . . . . . . . . . . . . . . . . . 38 38 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Discussion of Alternative CFC Formulations . . . . . . . . . . . . . . . . . . . 40 Mold Release Agents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 41 Lubricants for Electric and Electronic Equipment . . . . . . . . . . . . . 43 Lubricants for Pharmaceutical Pill and Tablet Manufacture . . . . . . . 45 Solvent.Cleaners. Dusters and Coatings for Electric/Electronic Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46 Metered-Dose Oral and Nasal Inhalation Pharmaceutical Products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48 Contraceptive Vaginal Foams. . . . . . . . . . . . . . . . . . . . . . . . . . . 60 Mercaptan (Thiol) Warning Devices . . . . . . . . . . . . . . . . . . . . . . . 62 Intruder Alarm Devices. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62 Flying Insect Sprays for Food-Handling Areas . . . . . . . . . . . . . . . .64 65 Flying Insect Sprays for Aircraft . . . . . . . . . . . . . . . . . . . . . . . . Flying Insect Sprays for Tobacco Barns . . . . . . . . . . . . . . . . . . . . 66 Aircraft Maintenance and Operation Sprays . . . . . . . . . . . . . . . . . 67 Military Aerosols . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 68 Diamond Grit Sprays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69 CFC-115 for Aeration of Puffed Food Products-Certain Limitations Applied . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69 70 Tire Inflators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Polyurethane Foams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71 71 Chewing Gum Removers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72 Drain Openers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Chillers-Medical . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72 Boat Horns. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -72 -73 Non-Electric/Electronic Dusters . . . . . . . . . . . . . . . . . . . . . . . .
Contents and Subject Index
ix
Microscope Slide Cleaners and Related Products . . . . . . . . . . . . . . 73 Solvents-Medical . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74 Contingency Products. Including Unauthorized Uses . . . . . . . . . . . 75 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75 5 . PROCEDURES FOR AND COSTS OF SUBSTITUTING ALTERNATIVE FORMULATIONS FOR CFC AEROSOLS . . . . . . . . . . 77 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 77 Cost of Converting Filling Lines . . . . . . . . . . . . . . . . . . . . . . . . . . . 80 Methods and Costs for Developing Alternative Formulations 83 for CFC Aerosols . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Mold Release Agents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85 Lubricants-for Electric/Electronic Equipment . . . . . . . . . . . . . . . 86 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88 Lubricants for Pharmaceutical Pill and Tablet Manufacture . . . . . . . 88 Solvent.Cleaners, Dusters, and Coatings for E'-ctric/Electronic 91 Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 93 Metered Dose Oral and Nasal Inhalation Pharmaceutical Drug Products (MDIDs) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96 Contraceptive Vaginal Foams (Human Uses). . . . . . . . . . . . . . . . . 96 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98 98 Mercaptan (Thiol) Warning Devices . . . . . . . . . . . . . . . . . . . . . . . 99 Intruder Alarm Device Canisters. . . . . . . . . . . . . . . . . . . . . . . . . Flying Insect Sprays for Food-Handling Areas . . . . . . . . . . . . . . . 100 Flying Insect Sprays for Aircraft . . . . . . . . . . . . . . . . . . . . . . . 101 Flying Insect Sprays for Tobacco Barns . . . . . . . . . . . . . . . . . . . 102 Aircraft Maintenance and Operation Sprays . . . . . . . . . . . . . . . . 102 103 Military Aerosols . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . CFC-115 for Aeration of Food Products-Certain Limitations Applied . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104 Excluded Products. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104 Tire Inflators . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104 Diamond Grit Spray . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105 105 Polyurethane Foams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Chewing Gum Removers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106 Drain Openers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106 Chi1lers-Med ical . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 106 Non-Electric/Electronic Dusters . . . . . . . . . . . . . . . . . . . . . . . . 107 Microscope Slide Cleaners and Related Products . . . . . . . . . . . . . 108 Solvents-Medical . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108 110 Boat Horns . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Contingency Products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110 111 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Procedures for Changing from CFC to Alternative Formulations. . . . . 114 114 Research Phase . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Contents and Subject Index
x
Manufacturing Preparations . . . . . . . . . . . . . . . . . . . . . . . . . . . Sales and Marketing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Production . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
114 115 115 115
.
6 CONCLUSIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117 Aerosol Uses for Which CFCs Are Difficult t o Eliminate (and 117 Possible Interim Reformulations) . . . . . . . . . . . . . . . . . . . . . . . . Mold Release Agents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119 Lubricants for Electric/Electronic Uses . . . . . . . . . . . . . . . . . . . 120 121 Lubricants for Pharmaceutical Pill and Tablet Manufacture Solvent.Cleaners. Dusters and Coatings for Electric/Electronic Equipment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 122 Metered-Dose Oral and Nasal Inhalation Pharmaceutical Products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 123 Contraceptive Vaginal Foams (Humans). . . . . . . . . . . . . . . . . . . 123 Solvents-Medical . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 124 Potential for Reduction of CFC Use in Exempted and Excluded Aerosols. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 124 Scenario One . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126 Scenario Two . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126 Scenario Three . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 126 Scenario Four . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 127 Near-Term CFC Reductions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 127 Longer-Range CFC Reductions . . . . . . . . . . . . . . . . . . . . . . . . . . 132 133 Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
......
REFERENCES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
134
APPENDIX A-ADDITIONAL INFORMATION ON MDlDs . . . . . . . . . . . 135 APPENDIX B-DOT REGULATIONS FOR COMPRESSED GASES . . . . . . 142 APPENDIX C-METRIC
(SI) CONVERSION
FACTORS
. . . . . . . . . . . . . 148
PART II ALTERNATIVE FORMULATIONS AND AEROSOL DISPENSING SYSTEMS SECTION I: ALTERNATIVE AEROSOL FORMULATIONS . . . . . . . . . . 150
. ..................................... 2. FORMULATION GUIDELINES . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 INTRODUCTION
General considerations. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Concentrates . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Flammability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Pressure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
151 162 162 165 167 170
Contents and Subject Index Materials Compatibility
.............................
xi
170
3. EXAMPLE NON-CFC ALTERNATIVE FORMULATIONS . . . . . . . . . . 173
Cosmetics. Toiletries. and Personal Care Products . . . . . . . . . . . . . . 173 Hair Sprays . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 173 Hair Lusterizers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 177 Hair Mousse . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 179 Containers for Hair Setting and Conditioning Mousses 191 Other Mousse Products. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 193 Shave Creams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 209 Underarm Products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 213 Colognes and Perfumes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 226 Household Products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 230 General Comments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 230 Window Cleaners . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 236 Spray Starch. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239 Heavy-Duty Hard-surfaceCleaners . . . . . . . . . . . . . . . . . . . . . . 243 Carpet and Rug Cleaner . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 249 Silica-Based Absorbent Fabric Cleaners . . . . . . . . . . . . . . . . . . . 253 Air Fresheners . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 254 Disinfectant/Deodorant Sprays . . . . . . . . . . . . . . . . . . . . . . . . 256 Disinfectant Cleaners . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 257 Paint Products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 261 Furniture Polishes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 264 Car Windshield De-lcers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 266 Pesticide Aerosol Products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 268 Insecticides . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 268 Insect Repellents. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 271 Pharmaceutical Products. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 271 Industrial Aerosol Products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 274 Adhesive Spray . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 276
.........
SECTION II: ALTERNATIVE AEROSOL DISPENSING SYSTEMS
.
. . . . . 278
1 INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
.
279 279
2 DESCRIPTION OF AEROSOL PACKAGING ALTERNATIVES . . . . . . 285 Bag-in-CanTypes. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 285 The Sepro Can . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 285 Bi.Can . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 303 Compack . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .307 Alucompack . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 308 Micro.Compack . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 309 Lechner (Types I Through I V ) . . . . . . . . . . . . . . . . . . . . . . . . . 310 Presspack . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 312 Other Bagin-Cans . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 312 Piston Cans . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 313
xii
Contents and Subject Index The Mira-Flo Can . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 313 315 Other Piston Cans. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The Boxal Pump Dispenser . . . . . . . . . . . . . . . . . . . . . . . . . . . 317 Independent Bagin-Can Systems . . . . . . . . . . . . . . . . . . . . . . . . . 319 Pump Sprays-Aspirator Types. . . . . . . . . . . . . . . . . . . . . . . . . . . 325 Pump-Sprays-Standard Types . . . . . . . . . . . . . . . . . . . . . . . . . . . 327 327 The Finger-PumpSprayer . . . . . . . . . . . . . . . . . . . . . . . . . . . . Trigger-Pump Sprayers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 337 Finger-Pump Extruders. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 337 Trigger-Pump Extruders . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 338 338 Dispensing Closures . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Pressurizing Dispensers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 340 340 Twist-N-Mist II . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The Exxel Systems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 344 The Mistlon System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 348 Airspray . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 351 352 The Werding Nature Spray.Systems . . . . . . . . . . . . . . . . . . . . . . Miscellaneous Aerosol Alternatives . . . . . . . . . . . . . . . . . . . . . . . . 353 353 Insecticide Vaporizers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Stick Products . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 355
3. SUMMARY
.........................................
APPENDIX A-METRIC (SI) CONVERSION FACTORS
.............
359 361
Part I Background and Overview The information in Part I is from Alternative Formulations to Reduce CFC Use in U.S. Exempted and Excluded Aerosol Products, prepared by Thomas P. Nelson and Sharon L. Wevill of Radian Corporation for the U.S. Environmental Protection Agency, November 1989.
1
1. Introduction
The use of cblorofluorocrrbonr (CFCs) in specific categories of aerosol propollant use considered "aonessentirl' vas h n n e d in the U.S. by regulations p r o d g a t e d in 1978 (1). An aerosol v u defined as a package comprising a self-pressurized, non-recumable container constructed of metal, glass. or plastic that conuins a fluid product and that is fitted vlth a valve for expelling the product as a spray, Liquid. gas. foam. powder, or paste. bumad CFC propollants included the fully-halogenated types: CFC-113. CFC-114.
In view
rpd
The
CFC-11, CFC-12.
CFC-11.5.
of the recent renemd interest in reducing worldvide production
and consumption of CFCs and other c b o i c d r implicated in the depletion of the
Earth's stratospheric ozone layer, the U.S. Environmental Protection Agency (=A)
undertook chis study of currently exempted and excluded CFC aerosol
applications aad their alternatives. The EPA and the Food and Drug Administration (FDA) initiated and supervised the three-stage program from 1977 t o L978 to eliminate most uses of
f u l l y halogenated CFC propellanrs for aerosol propellant applications except for 'essential uses:
If the CFC in the product functioned as more than a
propellant or dispersant, it v u considered 'the product'
and excluded.
product" or "part of the
R m agencfes held the concepcr of "product" and
"propellant" to be outually exclusive.
Also. the EPA and FDA evaluated the
need for certain "essential' aerosol propellants.
These were products that.
for reasons of safety. health. or national security, required a CFC propellant.
The initid EPA evduation rmsulted in a list of approxirsacely 14
general applicatioru considered exempt.
2
Introduction
In th. years f o l l o v i n g u m p t i o n r were tendered.
3
the transition. a few a d d i t i o n a l p e t i t i o n s f o r
Sap. w e r e accepted.
In a d d i t i o n . agency c l a r i f i c a Some produces
tion of th. u c l u a i o n o f specific product types w a s requested.
were added t o the exempt list u the r e a u l t of these activities. Exemptions -re applied to th. product c a t e g o r y , rather thrn t o specific products o r brand
MUS.
This report 1d.ntifies technically f e u i b l e method. f o r reducing CECs i n
a e r o s o l products without m r s e e f f e c t s on human l i f e and health ( i n h a l a n c s . p h u n r c e u t i u l tablet p r e s s lubricants), military preparedness ( l u b r i c a n t s f o r
electronic g e a r ) . and the economy ( c l e a n e r s and c h i l l - t e s t e r s f o r compucer equipment).
The A u g u s t 1988 &PA r e g u l r t i o a r (2) implement the Honereal Protocol ( 3 )
The r e g u l a t o r y mechmirr t o Implement the Protocol is d i f f e r e n c from the 1978 a e r o s a l p r o p e l l a n t ban.
Rather than develop t e y l a t i o n s s p e c i f i c t o each
fadustry a p p l i c a t i o n (such aa a e r o s o l p r o d u c t i o n ) , the e n t i r e supply of f u l l y halogenated chlorofluorocarbons u l l l be reduced. The Hontreal Protocol of 1987 and t h e corresponding EPA Final Rule co implement che Protocol r e q u i r e the following reductions i n c a l c u l a t e d l e v e l s of c o n a o l l e d CFCs: Beginning July 1. 1989. a f r e e z e a t 1986 consumption and production
levals of CFC-11. -12. -113, -114, and -115 on t h e b a s i s of t h e i r relative ozone d e p l e t i o n veights; Beginning mid-1993. a reduction of these CFCs eo 80% of 1986 l e v e l s ; and
-
Beginning mid-1998, a reduction of t h e s e CFCs eo 50% of 1986 levels.
4
Alternative Formulations and Packaging to Reduce Use of CFCs
In hy.1989, &legates o f the nations party to the Protocol met in He1rinLi and agreod on a fiva-point declaration t o strmgthen the Protocol. ‘zh. fiw polntr arm u follows: Phue
Ou+
later
ehrp tho y u r 2000.‘
&
coautmption and production of ozoru-depleting CFCs “not
soon u feuible, phase out halonr and concrol and reduce ocher
o+op.-&pleting substances th.t contribute significantly to ozone
dap letion. kcolorrto developmont of environmentally acceptable alternative
subetf~utingchemicals, producu‘. and technologies. H d p &v8loping countries by providing information, training, and POSSibly funding t o faCflitPt0 adoption of acceptable alternatives. Urgo all s u t e s &at
have not already done so to join the Protocol.
OBJECTIVES AND ORGANIZATION OF THE REPORT
The purposa of cha present report is 1) after reviewing the application. availability, and cost-effectiveness of CFC alternatives, to determine if suitable non-CTC alternatives or alternatives vith lover CFC content can be
substituted for thoae aerosol products in the U.S. that still use CFCs, and 2 ) to determine tho steps necessary to convert to the best alternatives.
Section 2 of ;his report &scribes
exempted and excluded CBC aerosol
applications in the U.S.. as well as thosa duplications not covered by the regulation.
Section 3 discusses the current U.S. consumption of exempted,
excluded, and nonregulated CFC products. formulations are discussed Ln Section
Suggested alternative aerosol
0 , and ,&a
m n c and application are explored in Saction 5.
economics of their develop-
Introduction
5
Section 6 presents the conclusions of the study and discusses the most promising alternative forarlations for CFC aerosols remaining in use in the
U.S.
Baaed om suggested scenarios for introducing the alternatives. the
following reductions Fn CFC aerosol usage in the U.S. are judged possible (see Sections 4
pad
61:
1990 Usage CFC Roducts
Present Connuptiop
1.50 Hold Roleases Lubtfcm+s 1.90 (electric/electr&c) Lubricants-Tablets 1.00 Solvents6.00 ( electric/electronic) ,%ID (Hetored-Dose 3.90 L n & l a t Drugs) Contraceptives 0.10 S o l ~ ~ - H . d i c r l 0.60 10.50 ALLOTAEBS
-
Units:
S c d o Orm
1990 Usage Scenario Tw
1995 Usage Scenario Three
2000 Usage Scenario Four
1.50 1.90
1.11 1.10
0.00
0.00
0.00
0.00
1.00
0.68
0.00
6.00
4.20
0.00
0.00 0.00
4.00
4.00
5.25
0.50
0.10
0.10 0.46 0.00
0.00 0.00 0.00
0.00
0.60 0.00
0.00
-
-
-
-
0.00 -
25.50
15-00
11.65
5.25
0.50
HH lbs/yr.' In addition, CFC control measures may need to be examined f o r certain
self-pressurized products not covered in c h i s report. €2.4
For example, in 1977. granted an exemption to flying insect sprays used in tobacco b a r n s . The
exemption was not limited by container size. Depending on the barn size and layout. one insecticide averaging 35% Vapona (2,2-dichlorovinyl dimethyl phosphate and r o l a t d corpormds) aad 6 5 % CFC-12 was used in sizes ranging from L2 Av.02. to 25 lbs.
For this product. considering density, the "aerosol"
containers are limited to n e t weights of approximately 24 Av.02. (1 lb. 8 or.) or less.
'Readers mro familiar v i t h metric units may in Appendix C.
us0
the conversion factors
2. CFC Aerosol Applications Exempted in the U.S. Table 1 lfsu CFC u r o r o l applications e x q t e d from E A ' S and FDA's 1970 replationr. =A's
final nrle-P.kin(l oxcludrd aerosols contafnfng propellant only,
aerosols that do
In such instances the Alro, vheu che CFC is an actfva ingredient. tho aerosol product assume. a nonregulrted s t a t u s . The concepts of "producc, active tngadient. and concentrate" and 'propellant' are held to be mutually i.0..
MI:
propol another material.
p r o p e l l a a ~ & c ~ the s pboduct.
exclusive. and regrlrtlonr only deal with aerosol propellants.
Table 2 lists
t h m CFC aerosol applfcrtioar that are exc1ud.d from the ragulatton.
The rationale applfed in 1978 and 1979 by EPA and the FDA vhen considerfn8 proposed exemptions inc1ud.d the following: %.
need for a n o n f l d l e product;
The five years often taken by the Drug Division of the FDA co
approve an Amended New Drug Application (applies to bronchodilacors and other inhalants, and vaginal contraceptive foams for human =e) ;
Required solvency and purity profiles. e . g . , CFC-113: Doctrine of cquivalency--dut highly similar products cannot reasonably be treated differently;
6
CFC Aerosol Applications Exempted in the U.S.
TABLE 1. SPECIFIC
=SOL
PROPELLANT APPLICATIONS
-
7
1978
1.
h l e u e a g e n u f o r molds used t o producm p l u t i c and d a r t o m e r i c materials;
2.
Lubricants f o r r o w - q p a presr-prmch.s f o r the production of pharu c o u t l d tablets:
5.
krbricaau. c l u u o r - s o l v e n u . dusters o r coatings f o r i n d u s t r i a l / institutional applicaciana t o e l e c ~ r o a f co r e l m c t r i c a l aqufpmont ;
4.
m r u p t a n stench varning d.ofcms f o r minor;
5.
Ocher varning -cas, horns, e t c . ;
6,
Flying insect p e s t i c i d e s f o r uae in c o v r c i a l food handling a r e a s , u c e p t vhen applied by t o t a l rmlease o r metered valve aerosol devices;
7.
Propellaata f o r flying insect p e s t i c i d e s f o r the fumigation of a i r c r a f r ;
a.
Flying h a a c t spray f o r tobacco barns;
9.
m.ter.d
----
_-
such
M
L n W r alarms. boat horns. bicycle
dose inhalant drugs, as follovs:
Steroid drugs f o r hrnmr, ( o r a l and nasal) Ergotmine t a r t r a t e drugs, and Adrenergic bronchodilator drugs ( o r a l ) ;
LO.
Conttaceptivm vaginal foams f o r human use;
11.
Aerosols f o r the maintenance and operation of a i r c r a f t ;
12.
Aerosols necessary f o r the military preparedness of chc United Staces o f America;
13.
Diamond g r i t sprays; and
14.
CFC-115 (CCIFz-CF,) f o r t h m a e r a t i o n of puffed food products.
8
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 2. CFC as Active or
1. 2.
3. 4. 5. 6. 7.
a.
9.
LO. 11. 12.
EXCLUDED CFC AEROSOL APPLICATIONS
Sole Inuredient
CFC-12 used as a polyurethana blowing agent (insulation foams); CFC-12 apd CFC-lN mixtures wad in tire inflators: Corrrin spacialty f-, vhips, and puffs h d l d solvmts such as sFlicop.-bued badage adhesive (CFC-113) and W g a &rlva r.I.0y.r (CFC-113, vith 5% a,): CFC-12 and CFC-114 refrigoration .ab air-conditioniaq system refill unit* : Drain opanars: Microscop. slid. cleumrs : Colprter damars a d dusters (equivalent to numbor 3 in Table 1); Boat horns; Halon fire ertinguishars (tha typos containing 952 Halon-1211 and 5% CO, may not ba oxcludad); Intruder dun sonic devices for homas and card; and Sldn chillers--for medical purposes.
'The aerosol indurtq recognizer thase products as .aerosols" in surveys and closo irmolvemant u i t h tha iurketing firms.
CFC Aerosol Applications Exempted in the U.S.
9
Limited availabilirjr of rubstitute propellants or products; Srnatospheric
BATIOUALE
mx
XDXPTED
OZON
impact, e . & ,
production tormrge Per year; and
USES OF CFC AEROSOLS
This section vi11 s p e e i f f d l y ezaminm the rationale for exempting certain aerosol products from the 1978 baa on CFC use. m e r e possible, produces in siailar groupings vi11 be treated u a unit.
w
J
&(For ool&
to produce plutics and elastomers for medical rpplicationa. Also, for mold ch.nbers in punch presses used t o produce pharmaceutical pills a d tablets.)
CFC-11 and CFC-12 are w e d . sometimas vi&
CFC-113. in an industrial
environment. The solvent propellant system must be extremely pure to prevent product contamination.
The system must also be compatible vith the item being
formed to minimize such effects u colorant bleed, distortion, and filler micro-crgstalliration.
Since the solvent/propellant system may be used
repeatedly. and u u a l l y i n a controlled environment vich negative-pressure settings, minimum f l d i l i c y , preferably n o d - b i l i c y .
is an important
attribute. The solvent must be volatile so that all buc ppb traces arc gone by che time che product is packaged and possibly radioisotopically sterilized. CFC-11 and CFC-113 provide this volatilicy. vhile also modifying the particle size distribution of the spray to achieve opt%en
the application v u
M&
surface coating efficacy.
for CFC-11. CFC-12. and CFC-113 to be
exempted from che regulacion. che only available nod-ble propellant vas HCFC-22. The possible nonflammable chlorinated solvent alternatives vere methylene chloride and 1,l.l-crichloroechane ( 0 ) . Boch contain considerable amounts of mixed inhibitors (free-radical chain stoppers), such as 1.4-dioxane and nltxome-. The effect of these high-solvent substances on molded
10
Alternative Formulations and Packaging to Reduce Use of CFCs
u d l c a l p r o d u c u v u s o a o t i m s d o l e t e r i o u r ; choy s o m a t h o r v o l a t i l i z e d from
th.r w i t h d i f f i c u l t y , and the c o n d z m t i o n e f f e c u of the v a r i o u s i n h i b i t o r s d d have c u u a d tho FDA t o r e q u i r e a peru+rrting o v a l r u t i o n of product putty and toxicology.
E.+r.wly pure CFC-12 and CIC-113 u e used t o luk. sprays' o f varying p u t i c l o sire distribution f o r t r e a t i n g f i n f s h a d e l e c t r i c o r e l e c t r o n i c
circuit boards, cuwrs. computer lay-mu. and r i m f l u "hi-tech' a r t i c l e s . U h r e l u b r i c a n t a p p l i c a t i o n o r solvene-bued cleming is r e q u i r e d , a mixture of about 25Q CFC-12 and 75% CFC-113 is tho choice.
Coating s p r a y s ( o t h e r than
l u b r i c a n u - - r u c h u a n t i - s t a t i c ) MY us0 30-35% CFC-12; t h e remainder is CFC113.
Duster sprays o f t o n use 100% CFC-U. Vapor-phase defluxers use v a r i o u s
blonds of CFC-12/113, dopending on the s p o c i f i c a p p l i c a t i o n . CFC-113 is p r e f e r r e d because of its e x t r . ~p u r i t y vhen purchased i n grades s p e c i f i c f o r tho purpose and because o f its c o m p a t i b i l i t y v i t h mater-
ials of conseruction.
It can e f f e c t i v o l y r e w v o o i l s . s o l d o r by-products,
g r e u o s . inorganic d u s t s , and o t h e r dotritus vithout adversely a f f e c t i n g e l a s t o w r s , p l a s t i c s , and weals.
Any more c r i t i c a l treatment of the s u b j e c c
vould hiwe t o consider individual a p p l i c a t i o n s .
The firms soaking an exemption claimed that t h e r e vas no s u b s t i t u t e chemical v i t h the e x t r e w p u r i t y , n o n f l d i l i t y . m a t e r i a l s c o m p a t i b i l i t y , and the v o l a t i l i t y of CFC-113.
Ono manufacturer of personal computer boards LO t o 15 o p e r a t o r s sprayed residue m a t e r i a l s from f i n i s h e d boards a t the r a t e of t w o t o f i v e b a u d s per minute. Besides Leaving t r a c e s of petroleum o i l s on the boards, the use of hydrocarbon g a s e s , such as i s o bucane. would have caused a f i r e h a r d in an a r e a h e r e t e s t i n g equipment vas needed that could not be purchased i n explosion-proof designs.
c i t e d a room & r e
CFC Aerosol Applications Exempted in the U.S.
11
Typically. t h s e &vices a r e w e d in mine tuamels to varn of the buildThe devices are
up of seeping mch.ru and/or carbon a o n o x i b n h l e gases.
operated by airand
small, parubla miffel-tarter that continuowly monitors the
& t ~ -leu
Bridge circuit.
g a s u by tho dffierentiating a c t i o n of a Wheatstone The s t m c h M c e is preferred to siren. since some miners
may be operating air d r s or drills and MY also h v e hearing deficiencies because of their long exposure to the 110-docibel noise of these cools. The typical aerosol container, equipped v i t h a piseon-operated actuational device, COPUIM an ethyl mercaptan (ethylthiol) stenching agent in a m i x w e such as one
of the following: 3% 17% 8Q*
Ethyl Karcapcau
2r
E t h y l Mercaptan
1.1,l-Trichloroethme (6)
CFC-12 or
9aa
-
CFC 12
Uining companies seeking the exemption reported the life-saving actribute of the product, also pointing out that a nonflammable composition v u necessary, since 1) the entire can w a a discharged quite rapidly and 2) there v u already a buildup of €lamable gases; deliberately releasing more
would seme to exacerbate an already hazardous situation.
Other self-pressurized varning devices include home and car intruder alarms, boat horns, etc. They generally consist of 100% CFC-12. Since large quancitier of gas are released at one time--often the entire can contents-under a variecy of closed or open environmental conditions. the use of a
f l d l e propellant seemed w i s e .
(At the time the exemption vas sought, no
12
Alternative Formulations and Packaging to Reduce Use of CFCs
toxicologically s a f e . liquid honflanaable altemrcive propellant had been identified.)
The firms seokiry an exemption pointed out that products designed for +h. preservation of life and property should MC.
S u l l (though pa+entirllp dangerous) m
to . s u
and chore -re
110
of themaelver, be hazardous t
s were released each time,
available substitutes. Also, the production volume was
fairly lov.
w
(For use in c o m n r c i d food-handling areas. except for total-releaso and mater-sprays; also for killing
LNecu in and on aircraft and in tobacco vuehoures
.)
The produces for comercial food-handling areas have the following typical formula:
2r 1ar
Pyrethrins 6 Piperonyl Butoxide Toxicants
368
m-11 CFC 12
bb8
Petroleum Distillates (Food Grade)
-
Minor amounts of methylene chloride and/or iso-butane have also been included in some products as less costly alternatives.
Two other approaches were proposed but rejected. The petitioning marketers vere .not interested in providing total release
or macarspray products to these food-handling establishments and suggested that EPA exclude those forms from the exemption they vere seeking. Aircraft fumigacion 1s used co prevent the antry of unwanted insects inco che United States.
In some instances, the products also contain a disinfeccanc ingredient to reduce surface-contact bacteria. molds, mildew. yeasts. rickettsia. virus, and other micro-flora.
CFC Aerosol Applications Exempted in the U.S.
13
Regulations v q among coun+ries, b u t many r e q u i r e fumigation v i c h n o n f l d l e f o r n u l a t i o a r in a e r o s o l d i s p e n s e r s . both a t their home p o r t s of mcry and in aircraft of their r e g i s t e r . In the U.S., the American P i l o t s Association hu esublished
coda. 8ccepted by the c u r i e r s , that only
a e r o s o l s shall ba rued for fuelgation.
-la Of
8
th. c1-1
h.rOMUdC8
This is a l s o a r e g u l a t i o n
hUd.
Alrcraft are not eade explosion-proof, and the p o s s i b i l i t y e x i s t s chat Ln a sensitive area by a poorly informed person could lead to a fire, although not t o an explosion ( 9 . 6 g of hydrocarbon p r o p e l l a n t is capable of b r i n g i n g 55 U.S. Gallons of a i r to t h e flammable
ucess, localized spraylug
rauge).
In the p e t i t i o n for exempting these p e s t i c i d e s from the r e g u l a t i o n , che option of a water-brred product v u considered, b u t it w a s r e j e c t e d f o r t h r e e rerrons: v u
1) ic still contained 30 t o 32% hydrocarbon p r o p e l l a n t . although i t
technicdly n o n f l h l e by strndnrd t e s t m t h o b then f n use; 2) t h e
h e a v i e r p a r t i c l o s e e caused fall-out t o ' a f f e c t the passengers and polished s u r f a c e s ; and 3) because of t h e f a l l - o u t , the odor o f the t o x i c a n t s vas more p a r s i s t e n t than vith true space sprays.
The exemption allowed f o r tobacco barns and warehouses has a p p a r e n t l y been l i b e r a l i z e d t o cover tobacco vareho-.ses and food warehouses if they c o n u i n tobacco products.
Nevertheless, this is a
.
a p p l i c a t i o n . and
s o u users have converted. because of economic incencives.
The p e t i t i o n claimed chat tobacco l e a v e s , dusts, and granules a r e boch c o s t l y and v e r y flrPuble; thus, n a m a b l e sprays should n o t be used i n b u i l d i n g s chat c o n t a i n these materials.
Tobacco i n che d r i e d s t a t e is a l s o
highly absorbent and would p i c k up a c e r t a i n amount o f t h e e m u l s i f i e r s . f n h i b i t o r s . and o t h e r i n g r e d i e n t s of water-based f l y i n g insect s p r a y s , a d u l t e r a t i n g the tobacco.
14
Alternative Formulations and Packaging to Reduce Use of CFCs
(Steroida, ergotamine tartrate and adrenergic bronchodilator types.) This category rapreseuts about 4C of the U.S.
d o M S t f C aerosol u n i t in size. The usual range is from about 0.5 Av.02. (14 g or 10 rt) eo about 0.75 Av.02. (21 g or 15 A). The CFC cmtmt la 07 t o 96 percent. In general. 70 to 801 of the CFC content is CFC-12. Tho 0tb.r CFCI a r m CFC-11 and CFC-114. A typical formulation
volm, although th. products a r e vary -11
folious: 1.51
Solid Drug (hamrally povdered to 2-10 microns)
1.5C
excipieuu
12.01
CFC-11
10.01
CFC-114
75.01
CFC-12
The leas cop.(m solution typer use about LO* anhydrous ethanol as a corolvanc; h u t 8% or more CFC-12 is used in such producer to achieve the desired break-up of the spray. Unless the particles are within 0.5 to 10 microns in s i t e , they vi11 not penetrate beyond the extruaile cilia1 area and up t o the a l n o l l t tubes a d sacs where pulmonary abnormalities m y e x i s t . For example, Al-buterol, used in about half of a l l these products, requires deep penetration t o be effective.
To reduce thermally sensitive powdered drugs into the 2 - to LO-micron particle s i t e distribution, they MY be mixed v i a an appropriate non-solvent liquld o f high volatilfey into a slurry and then ground or milled.
ko
frictional heat is genarated. it fa instantly disstpated inco solvent vaming or ~ l a t i l i ~ a t i o n .Noam of the drug houaes hu explosion-proof equipment in their FDA-approved processing facllfties--nordo they have the Elamnabla gas detection &vices; blov-out walls; electroprotective systems; multi-stage, high-intensity ventilation: rad ocher system that would be needed ff the slurry liquld wore highly f l u r b l e [such u n-pentane (B.P. 98'F) or i s o Peneana (B.P.
-
-
86'F)I.
Co~equaatly. the slurrying agent must be non-
CFC Aerosol Applications Exempted in the U.S. 15
f l l r u b l e and available at a high level of p u r i t y .
fulfills et&
In
r.quir.uat.
-
s o n prellmlxury studles of
8
CFC-11 (B.P.
CFC-ll/hydxoe.rbon
-
74'F)
system, the hydro-
prop.llaaC v u found to a bad (stinging. ofly) t a s t e . especially if thm prodtact v u dorigmd f o r o r d entry, i n s t u d of nud inhalacion.
urbop
In 1977
.od 1978. tlm phumacmuticrl houses advised the
Divlsioa) of th. d a m facu. s t a t i n g that
110
FDA (Drug
alternatitn slurrying agent vas
d l a b l e f o r CFC-11, a d that noa-CFC propellants were inimical to product org.noleptics and perfornurce.
They also reported Chat, even i f nonflammable
and ochervise a c c e p u b l e altemrrtitns were available. they would require three
to f i a y e u r of davelopaeatd work. followed by a five-year study by the FDA
before nrrkatin$ approval could be obtained.
Crcs, th.se life-savlag
and ramodirl
Without a continuing supply of
drugs vould no longer be av8ilable.
These drugs wore marketed a f t e r extansim t e s t i n g by pharnnceutical firms and by the FDA (Drug Division).
Testing of an a l t e r n a t i v e formula would
have to proceed almost from the beginning and would take an estimated seven years t o coaplete.
The FDA favored the use of CFC-12/114 propellant blend
over the A-46 (lso-butane/proprn.) blend; the New Drug Amendment (NDA) granced
in the l a t e 1960s v u based o n l y on the CFC formula option.
Vqinrl f o u v are uet A Life-saving product. The exemption v u granted because. vhfle altemrrtivm p r o p e l l a n u vere available, they could not be used until 0 . n ~y e u s of r e t e s t i n g had been conducted.
Also, the market f o r the
products v u rather so111. and only about 6 . 6 g of CFCa were used p e r average 3 Av.02. dispenser.
Had the usage level been higher. the FDA night have noc
g r a t e d the exemption. feeling that other routes t o conrraception were
r~.iiabie.
16
Alternative Formulations and Packaging to Reduce Use of CFCs
Durlng 1988, houovmr. tha FDA granted an NDA t o the Upjohn Company f o r a hair r e s t o r e r product. Tho mukoter pr0vId.d information t o the agency on producta using both CFC md A 4 6 (iso-butano/propra. blend) p r o p e l l a n t opclous. Dospite the Moatred Protocol .ad heightened concerns about t h e s a a t o s p h a r i c 02hpt. th. F'DA sdected only tho CFC o p t i o n f o r marketing. 'Ibr product is
( 2 Av.02.).
A
.ad con-
q u i c k - b r e r l i n g f o u , is quite small i n s i r e
less than LO5 CFC blend.
Thus, it is extremely
slmllu t o the contracoptiva vaginrl f o u in p r o d u c t / p a c h g e c h a r a c t e r i s t i c s . Ultlmatoly. it could c a p w e
for
Airctaft
A
s u b s t a n t i d market.
( I h l n t m n n c e and Operation)
L i t t l e information is available on these a e r o s o l s .
Along v i t h the
Flying Insoct FUPIgaats d l s c l u s o d abova, those a o r o s o l s includo l u b r i c a n t s , Considarationr such as safecy. high f l d i l i t y p o t e n t i a l - - t h e l a r g e s t a i r c r a f t can hold a h s t a tank t r u c k - s i r e d load of a v l a t f o n fuel--h#e l e d the American P i l o t s Associacion
c l m n o r s , .ad o t h e r industrial item. value. and
( M A ) and r e l a t e d organizations t o r e c o m n d the r e s t r i c t i o n of s e r v i c e
a e r o s o l s to nonflamable options. TM nonflamable options f o r a l u b r i c a n t a e r o s o l a r e the f o l l o v i n g : CFC Type:
- Winterized
25
S M I 30 Uotor Oil
55
Modified Dimethylsiloxane ( S i l i c o n e Oil)
235
l,l,l-Trichloroethane
405
CFC-11
305
CFC-12
CFC Aerosol Applications Exempted in the U.S. 17
Alternative :
2x 5% 83X
SAE 30 Uotor Oil
-
Winterized
Uodified Dimethylsiloxane (Silicone Oil) l,l,l-Trlchloroeth~ne
5%
Odorlesa Uinerd. Spirits (Flash Point
5%
Cub00 Dioxide
129'F
( 5 4 . C ) Sat-A-Flash Closed Cup)
Following are tua options for spray paints for touch-up and corrosion control : CFC Type:
551
Aerosol Paint Concentrate (Gonerally Acrylic)
Hydrocarboa:
45x
CFC-12
5%
Aerosol Paint Concentrate
15%
(hamrally Accrylic) Acetone or Mechylene Chloride
30X
Hydrocarbon B l e d A-85
(namable)
52X Propme and *8X Iso-butane
Although APA would not approve of the hydrocarbon version. che Factory .Xu&
Research 6 Engineering Company has shown that the two formulations are
virtually indistinguishable in terms of intrinsic flammability. Hilitam Aerosols (For continuing military preparedness) The U.S. Armd Semicar purchases about 1,000,000 pounds of CFC-LZ/CFC-l1-propdl.d insecticides a year by contract.
Uost are Flying Insect Sprays for troops, but some are specialty items, such as Uasp and
Hornet Sprays with CFC-113, designed to protect maintenance personnel vorking on power stations and u t i l i t y lines. Significant numbers are exported to military h s e s overseas.
Alternative Formulations and Packaging to Reduce Use of CFCs
18
The Annd Forces also purchases various o t h e r a e r o s o l p r o d u c t s . and say at their o p t i o n select CFC f o r a r l a t i o n s , a p p a r e n t l y v i t h o u t s p e c i f i c j u s t i fication. Tha d a r o f CFC u r o s o l s is thought t o be r e l a t i v e l y lov. and
their us0 1s restricted t o niliurp aircraft ~ i n t e n m c e ,computer & - d u s t i n g ,
m m d fln finding, syputic u p a spray.. and specialty l u b r i c a t i o n .
Very l i t t l e information could be found. except that tho market is
ninucule. Wont. Allfad-Si@. LP
No
application.
‘sand blasting’
OIU
and Racon had no record of selling CFCs f o r such could k r @ m using such a product except f o r diamond
e x t r e a o l y l a u d mtallic surfacer t o micro-etch them.
Wont, vhich is the o a l y remaining doustic s u p p l i o r of CFC-11s f o r
this use. has not s o l d the product t o a whippod cream manufacturer o r food
company i n many y e u s . The original, whipped cream c o n s i s t e d of w a t e r d i s p e r s i o n s of e i t h e r
natural o r s y n t h e t i c whipped cream i n g r e d i e n t s , p r e s s u r i z e d vith CO, and 9,O ( o r t h e Whim’s i l h t u r e of there food grade p r o p e l l a n t s ) . For economic reasons, f o d a t i o n s vera then limited t o syntheeic vhipped creams v i t h
nitrous oxide (q0) p r o p e l l a n t .
The lfmiced s o l u b i l i t y of t h e N,O gas forced
marketers t o f i l l c a s t o o n l y about 55 t o 601 by -1pressures of NzO.
and t o use maximum
Otherulsa. th. product becaam ‘soupy” na8r the end of the
E m .
F r o o 1968 through 1971. when food a e r o s o l d i s p e r s i o n s increased dramatically in chr aerosol induatry. W o n t devoloped t h e i r Freon (Food P r o p e l l a n t )
C-318 (chemically. parfluorocyclobutana). which could be added t o the N,O a t the rate of 3 t o 6 g per 9 Av.02. can t o givo a nuch more uniform vhip throughout the life of tha dispenser. It also allwed 2 co 3 a d d i c i o n a l
CFC Aerosol Applications Exempted in the US.
Av.02.
19
t o be included i n the can, a t the p e m l t y of slight "soupiness" near
the end.
A mica1 use of 4.5 g The problom v u that the c-318 cost $7.50/1b. p.r w fncroud th. fatorg cost by $0.20 p e r can. and even more if e x t r a product -re .dd.d to th. can. S h e th. mu u a u loolud the s m i f r e as t h e original ouos. CoIUIIyrs bought th. 1-r-priced o r i g i n 8 1 formulas, and C-318
Want then obtained FDA approval f o r CFG-115, which vas vel1 knovn b u t
navar used for uroaols bae8ure it c o a t $l.SO/lb.
CFC-115 vas t r i e d i n savor81 products d u r i n g the 1977 t o 1978 p t i t i o n period. Marketers based their p e t i t i o n s on the argument thrt their sales vould s e r i o u s l y decrease
'bail-aut' a t t r i b u t e s of CFC-115, thrt the p r o p e l l a n t had only one c h l o r h .+om and should pose a reduced threat to t h m ozone l a y e r . and c h a t only about 5 gram8 vmre needed p e r can. A t the t h . roughly 38,000,000 units of whipped erewere s o l d a y e u , o r 190 metric t o m e s p e r y e a r o f CFC-115.
vithaut the
if 8-m-
muketmr used the p r o p e l l i n e .
The mrketer team also advised the FDA dirt practical.
M
o t h e r p r o p e l l a n t s Were
Freon C-318 w a s unavailable except i n p i l o t q u a n t i r i e s , t h e Food
G r a d a hydrocarboru gave the product an o i l y , s l i g h t l y b i t i n g o f f - c a s t e , and
n i t r o g e n v a s coo insoluble. After the p e t i t i o n w u levels, the p r i c e of CFC-115 anocher option. Th. A u r i c Vent Release (Em) mociunlso cans,
granted, v i t h limits on product tyee and usage i n c r e u e d moderately.
Marketers began t o look ac
Can Company had r e c e n t l y introduced t h e i r Rim on the top double seam of t h r e e - p i e c e a e r o s o l
which opened up a mmber of a p e r t u r e s if the can became dangerously
overpressurized.
The Deprrcment of T r a n s p o r t a t i o n (DOT) normally l i m i t s i f the cans v e r e ordered v i t h RVR
a e r o s o l p r e s s u r e s t o 180 p s i g a t 130'F
fixtures. m e product v u nonflirPrrble and not ocherwise hazardous i f i t d i d escape the c o n t a i n e r . U l t h c e l p , DOT granced an f n d u s t r y p e c i c i o n . which alloved marketers t o i n s e r t 17t more N,O
gas i n t o the product.
This reduced
20 Alternative Formulations and Packaging to Reduce Use of CFCs
the "soupineso" problem and slowly led to the complete eliminarion of CFC-Llj in these products. At least two firas are testing CFC-115 in anhydrous "edible whip"
products of tho general tpp. recently patented by the Ring Chemical Company in New Jersey.
It gives thu a tmtter taate than the 3% Propane mentioned in the
paten=. Cno firm is conridorlng uae o f CFC-115 until yFC-134r (CH,F-CF,) corns onto the market a d can perhaps be approved as a Food Grade propellant. Propane may also be used, as a l u x resort.
RATIONALE FOR EXCLUDED USES OF CFC AEROSOLS
Tbe aerosol drain opener vas developed by Glanorene, Inc. (Secaucus. SJ) about 1972. The actuator consisted of a 2 and 11/16 inch plastic hemisphere with the exit hole at the apex.
The u n i t was upended over the drain hole of a
clogged sink and pressed donnrrrd. opening a valve to allow CFC-12 gas inco the drain pipe. which normally acted to blow the clog out of the gooseneck. Problems were encountered when drain liquids were blown out of the other drain
in double sink installations. Many bathroom sinks had side orifices to prevent overflow, and these sometinas acted as pressure outlets as well.
Pipe
connectors sometimes separated. The product consisted of 100% CFC-12. It did not meet criceria such as life-safety. high value in use, no available alternative. and minimum consumption of CFC gas-liquids. Eventurlly the high cost, excessively large can size. infrequency of use, and the many problems caused consumers to discontinue purchasing it. The franchise was sold to another marketer. and sales eventually ceased.
21
CFC Aerosol Applications Exempted in the U.S.
A blend of &out 75b ultrapure CFC-113 and 25b CFC-12 is used to f l u s h across cb. microscopa lam while it is s t i l l in the microscope h o l d e r . Loose dry rp.cimens. v i m e n s udmr o i l . druta. .ad o t h e r o b j e c t s are conveniently
flushed off. afar which auy r
,
w
g CFC-113 quickly evaporates.
This is a
great tim-saver f o r mq i n s t i t u t i d facilities vhere r e p e t i t i v e assays or r,uinrtioma are required.
F i r e t e n a d lumps of c h d n g gm a r e d i f f i c u l t t o remove from c a r p e t i n g
and o t h e r f l o o r coverings. but the task is g r e a t l y f a c i l i t a t e d by u s i n g a cheving gm f r e u a n t spray of CTC-12. which acts to drav down the gum t a m p e r r w e to about -6O'P (-51'C) surface.
Ib. -p&'
or lover by s u c c e s s i v e evaporations o f f rhe
chon becomes very b r i t t l e . able to be f r a c t u r e d o r The p i e c e s can then be removed vhile still
broken up w l t h a shrp blow. frozen.
This a e r o s o l product v u launched a f t e r the 1978 r e s t r i c t i o n s o r bans. I t is used mostly i n i n s t i t u t i o n s and accounts f o r about 350,000 l b s . of CFC-
12 p e r year. As of J u l y 1989, a t least fa0 major CFC s u p p l i e r s r e f u s e d sell any more CTC-12 f o r c h i s a p p l i c a t i o n .
The d i s p e n s e r s and a s s o c i a t e d horn devices
a r e made
to
by s p e c i a l c y f i r m s .
Arguments f o r continuing the use of lOOI CFC-12 in such packages a r e 1) che sense of v e i @ t i n e s s (15 A v . 0 2 . p e r can) c h a t connotes a good product: 2 ) the nonfl-bilicy
of t h e product
( S O M C ~ S
l a r g e amounts a r e r e l e a s e d a t one
time); and 3 ) marketers u s u a l l y manufacture their own products i n f a c i l i t i e s that a r e not explosion proof and vhere they could not s a f e l y produce the less
c o s t l y hydrocarbon p r o p e l l a n t a l c e r n r t i v e products.
22 Alternative Formulations and Packaging to Reduce Use of CFCs
Most of these m a r k r t e r / f i l l e r s produce a considerable v a r i e t y of a e r o s o l produces, all of thom p r e s s u r i z e d with CFC p r o p e l l a n t s o r c o n t a i n i n g 100% CFCb.
By Septombor 1989, several manufacturers had switched t o using HCFC-22
i n heavy w d l o d ( n o n u t o s o l ) c y l i n d a r s .
The p o r t a b l e dispenser area of this markot is divi&d i n t o
CJO
segments:
eh u r o a o l cppe and eh cylinbr - 0 . The a e r o s o l is l i m i t e d t o wo s i z e s : the w i n - p a c k of w 4 Av.02. CIPI i n a b e l t - c a r r i e r c a n i s t e r . with a common a c t u a t o r , ad the 12 t o 15 Av.02. pack, i n a red e-led, Kylnr-labeled aluminum contafnor, codod dad approved f o r use by Factory Mucual R&E Laborat o r i e s , U n d r m i t e r s Laboratories, o r 0x10 of the three o t h e r product t e s t i n g Laboratories recognized u reliable. The a e r o s o l s n e a r l y always use a blend of 20 t o 258 Halon 1301 (CSrF,) ad 80 eo 75# Halon 1211 (CBrClF,).
The
a pressure that w i l l allow the a e r o s o l t o pass s p e c i f i c y e t t h ~ w t i l l not exceed the 'DOT S p e c i f i c a t i o n 24" s p e c i f i c a t i o n f i r e testd. a t 130'F ( 5 6 * C ) , a d that is considered "self p r o p e l l of 180 psfg (euinm) o b f e c t i v a is to ob-
ing'
(not r e q u i r i n g
a' pressure gauge).
The c y l i n d o r o r tank porcion of this markot is s e v e r a l times l a r g e r . Several firma sell six o r more product s i z e s , o f f e r i n g the a e r o s o l s i z e f o r c a r o r boat and the l a r g e r s i r e s f o r home use.
The Halon is considorad " t h e product" s i n c e i t provides the f i r e extinguishing a c t i o n .
It is considered a l i f e - s a f e c y product.
Unfortunately,
bromine is a l s o 3 to 10 cimos more able t o d e s t r o y ozono than c h l o r i n e ( C l ) . dopending on che Halon molecule it is in. -der
Devices (For c a r s , trucks, and homos) Thhrse products a r e h i g h - i n t e n s i t y (100 t o 110 decibel) horns t r i g g e r e d
e l e c t r i c a l l y by varioua sensfng &vices.
h r g e amounts of gas a r e discharged
i n each alarm c y c l e t o achieve a p e r s i s t e n t s o n i c e f f e c t .
Because of c h i s ,
nonflammable g u is p r e f e r r e d , e s p e c i a l l y f o r indoor l o c a t i o n s .
The c o s t
CFC Aerosol Applications Exempted in the U.S.
23
premium f o r the CFCs (over the hydrocarbon a l t e r n a t i v e ) represents a small
incrennt of the Ov.ral1 M c e . (For pudicd purposes)
Those u r o s o l s a r e typically p d u g e d in dumfnum CUU. f i l l e d to 8 co 10 Av.02. vfth CPC-I2 o r blend of CFC-12 .ad CX-114. They a r e w e d by p w d i c a l persaoni.1 to parform nfnor t o p i c a l operations. such as the removal o f skin cancer. and i o f o r t h , by deadening I t mi&tha use of i n j e c t e d Novocaine and s b i l a r anesChillers have a l s o been used to shrink f i n g e r s and f a c i l i e a c e the
a splinter, thm
w a r t , a mn-wl.noOic
a f f l i c t e d area.
thetics.
r:.oovd of rings that have become too t i g h t . U s l u g f l i n v b l a gas r i t e r r u t i v e s i n a h o s p i t a l o r c l i n i c a l s e t t i n g would not be approved by the medical profession.
Roducts knovn to have such
propellants would aot be used, &spite t h e i r lower cost.
Dimethylecher is che
most e f f e c t i v e propellant f o r this application, buc i t is somewhat flammable.
A c y p i c r l formula f o r chis cype of aerosol p r o d u c t is as follows:
45*
Toluene d i - isocyanate
20r
Po.lyethylene Glycol (PEG) Derivatives
32r 3%
-
CFC 12 Dimthylether (DME)
The dimechylether is present only to bind up r e s i d u a l moisture t h a t can otherwise a c t t o c a u l y z e the reaction between the pro-polymer and che PEG
derivatives.
The f a c t that f t is a propellant is i n c i d e n t a l .
The CFC-12 is
used t o emure production of an e s s e n t i a l l y nonflammable, stable foam.
In cursory studies with foams containing hydrocarbon propellant blowing a g e n t s , i g n i t i o n was i n s t a n t and vas folloved by very rapid burning--with the product i o n of modest amounts of cyanides. cyanogen, and r e l a t e d toxic substances.
24
Alternative Formulations and Packaging to Reduce Use of CFCs
A p p r m i u t e l y 7Sr o f the u s u d t i r e i n f l a t o r c o n s i s t s of a v a t e r
disporrion of rerln and echyleno g l y c o l , ud a t r a c e of amphoteric s u r f a c t a n t ; 2% ia a hydrocrrban b l d A 4 6 ( b o - b u u r u md propano).
.
Uhon a t i r e is r e i d l a t a d vlth there p r o d u c u , the g u space v l l l then
caa+rin about 35 to 655 by v o l u m of f l d l e hydrocarbon gor. the Upper Explortva U
t
(UEL) of
This is w e l l
about 8.6 VZ f o r propme/butanes and
air, but in subsequant sctivitier ( r o w d i r e c t e d on the l a b e l ) this volume may bo d i l u t e d w i t h air i n t o the f l d l o range o f 1 . 9 eo 8.6 Vr. T i t e r in t h i s s t a t . have beon subjected t o removal. t o adjacent rim welding r e p a i r s , and t o o t h e r facldonZs &at r e d t e d in i n t e n d combustion, fragmentation of t h e t i r e , and s o v e r a , o f t e n f a t a l . injuries t o the o p e r a t o r . In 1906 Co-r
OIU
ruch marketer mot vith r e p r e r o n t a t i v e r of EPA and t h e C d r s i o n (CPSC) in Washington, DC. proposing t h a t
ROQICu Safety
tho ageneier pormlt tho rubrtitutton of the hydrocarbon p r o p e l l a n t by 559 CFC-
12/114 (40:60).
Tho agencies confirmed that they had the right t o do t h i s
because the CFCs would c o n a t i t u t e a p a r t of the product and because they had i n f l a t i n g action.
Within m o oontha the r e v i s e d product v u on t h e market.
I a w a u i t s i n c r e u e d . and during late 1988 another n n r k e t e r developed a
CFC-based t i r e i n f l a t o r formula. buc before going t o market, t h e marketers estimated that f o r every m i l l i o n pounds they purchased 18 s k i n cancers and 0 . 3 doatha would occur u n n u l l y .
The firm d i d n o t market the product.
The CFC p r o d u c t is cectmically i n f e r i o r and more c o a t l y than t h e s t a n d a r d hydrocarbon tlrpes; thorefore. i t has oaly boon marketed by one f i r m .
From 1981 t o 1986 a feu -11 theaa mor.
s p e c i a l t y firms produced CFC products of
For examplo. a firm formulated and packed an a b l a t i v e , very
h a r y foam using CFC-12/114 (u):60).
F i n g e r - r l n g r c o n t a i n i n g gemstones could
CFC Aerosol Applications Exempted in the U.S.
be p-ly
embeddad
25
Fn this foam while the back-side v
re-sizing operacioru by jawelerr.
u being welded during The s t o m a remained cool and did not become
serainad or crackad. Th. s~lf-fillerhad M explosion-proof facilities ( i n h i s b u u m t ) and v u comcerned about: the f l d i l f q of foam that carried
hydrocarbon praprllutta.
No o&
& d w m
v u f
of this m e .
non-dnag aorosol producu
Tvo firms purchum
d of Cpcs currmcly being used in the U.S. in
a
concentrate from the Dov Corning Corporation chat
contrins a silicone-bued adhesiw dispersed in CFC-113. Contract fillers pour the concentrate i n t o cans, seal them. and pressurize the contents vich cprbon dioxid.
(~0%).
Dov-Coming scienelstr say that alterrueives to CFC-113 are uniformly uaaccepuble for &e product.
For e u n p l e . the 7 to 8% of free-radical
reaction inhibitors in L,1.1-crichloroe~nehave unknown effects when broughc into conuct w i t h open wounds. The adhesive remover is required s i n c e the breathable silicone f i l m may bond the innermost layer of cotton gauze bandage t o the skin surface, preventing removal. Acetone, ethanol. and many other solvents are eicher ineffective or present toxicological problem. is required.
Thus, a self-pressurized adhesive remover
This consists of about 9 5 . 4 % CFC-113 and 4.6% CO,, in a fill
w e i g h t of 6.0 Av.02. per can.
Approximately 28 individual product types and groups have been or are being produced in aerosol formulas that conuin CFCs. C)%
This does n o t include
refrigeratfon/air conditioning refill products or ethylene oxide/CFC-12
g u sterilants, since these are not coruidared in aerosol exemptions or exclusioru.
26 Alternative Formulations and Packaging to Reduce Use of CFCs
Background data on each product or product group is provided. including
hou the CFC corporupr functions. ingredient(s) is ewlninod.
Industry's interest in preserving rhe CFC
In the excluded categories, petitions were noc
required, but metings wore often held, nonetholess, to firmly establish chat companies could go to p u k e + v i t h CFC-based products falling into these
utegorlor.
The p t i m u y reasons for requesting exempted s t a t u were the
uriavdlabilfty of substitutes. thr long tima dolays vhile obtaining an amended MIA from tho FDA. rolvoncy a d purity profiles (espocidly for CFC-113 u s e s ) . life-saving potential of tho product. and regulations in hospitals, aircraft organiutionr. e t c . against tho use of f l m b l e propellants in aerosols.
During tho 1977 to 1978 transition period. no nonflammable liquid propellant altexnatives to CFCs were toxicologically approved and commerciallv Today the sieuatlon has changed, with the clearance of available for US.. HCFC-22 and certain b l e d of HCFC-22/142b. and the forthcoming availability of HFC-1340. HCFC-123. HCFC-lklb. and HCFC-124.
As may tu anticipated, so-
exempted or excluded aerosol products are no
longer in use or have been replaced vith ones that contain alternative propellants. Houever. inhalant and solvent type products are steadily growing in s a l e s wLumo. See Section 3 for current U.S. consumption of CFCs and Section 4 for current and future alternative f o d a t i o n s for CFC aerosols. Section 5 presents a discussion of the costs of making these substitutions to alternative formulations.
3. Current U.S. Consumption of CFCs The mafn sources of Laformation f o r this r r c t i o n
a r e GFC manufacturers.
Product f o d u . m a r a g e product n e t weights, and the d i f f e r e n c e s i n t h e
sales v~luuasof similar produces azo estimated.
The production volume o f the
a e r o s o l industry ln units p e r year f o r 1988 is &terminad from v a l v e s a l e s and from c o a p u i s o n r w i t h the s w e y dau published $n 1987 by che Chemical S p e c i a l t i e s ~ W a c t u r e r ' sAssociation ( C S U ) and the C a n Maker's I n s t i t u t e (CXI).
C a c e g o r i c d volumes a r e then dorived by extending and augmenting che
& t a i l e d C S U data vith s p e c i f f c data from industry c o n t a c t s . DISCUSSION O F
TWE DATA
Table 3 shovs published data ( 5 ) i l l u s t r a t i n g an a n a l y s i s of t h e major catmgories o f the domestic CFC market.
Tabla 4 shows a number of product
c a t e g o r i e s of a e r o s o l s i n vhich C F C s a r e still being used, o r have been used
since 1978.
The U.S. CFC a e r o s o l market i n 1986 vas 24,000,000pounds.
grew by 3 . 9 % in 1987 t o 25,000.000 pounds.
It
The CFC a e r o s o l market in 1988 was
p r o j e c t e d t o be about 25,500,000 pounds (as of October 1 9 8 8 ) .
The f o l l o v i n g paragraphs e x p l a i n t h e information p r e s e n t e d in Table 4 .
The source of the daca obtained on CFC q u a n t i t i e s and u n i t s f i l l e d is a e r o s o l s in the same vay a s t h e U . S . Daprrment of T r a n s p o r t x i o n : p r e s s u r e - r a s i s t a n c c o n t a i n e r s with a c a p a c i t y of 50 cubic inches--819.35 mi. o r 27.71 f l u i d ounces. Larger c o n c a i n e r s , the a e r o s o l i n d u s t r y . vhich & f i n e s
designaced as c y l i n d e r s or tanks, do not have che a e r o s o l exempcion. and (in g e n e r a l ) are f i l l e d and marketed by firnu ocher than those in t h e a e r o s o l
27
28
Alternative Formulations and Packaging to Reduce Use of CFCs
3.
TiiE mLLY HALOGFJATED U.S. CFC "T OF 1986 (CFC-11. -12. -113, -114,AND -115) ( 5 )
nn
PRODUCr TYPE
PERCENT
p.friger.nu
60
290
n i m hanu
28
200
Cleaning AgeQtS
20
145
OTnEaS
12
85
Liquid Freon Freerant Aorosols Etchntr Scarilanu
POUNDS
100
720
a.
Liquid Freon Freeranc (LFF) is 100% CFC-12.
b.
Etchrncr a r e perfluoro- o r highly f l u o r i n a t e d CFCs, mainly CFC-llL, but including CFC-113, CFC-Ll5, and FC-116. They a r e d e l i b e r a c s l y dagradod by plasnr ares co produce HF for tfm e t c h i n g of e l c c c r o n i c
P-. E.
Tha sterilants c o n s i s t of the U.S. Pacenced. marginally nonf l e l e blend of L22 echyLene oxide (EO) and 882 CFC-LZ. 3 o s c is s o l d t o medical f a c i l i c i e s i n large c y l i n d e r s . buc soma is marketsd In L2 A v . 0 2 . a e r o s o l concainerr.
d.
The 'Cleaning Agents' a r e LOO2 CFC-113.
a.
m
-
million
. . ~ ...
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s ti z ... ~ "" ...
i ~ 0 "' 0 ~ ... <
4 ~ .,1 . ~
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~
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fa ~! :3fa. ~ =
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>
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'-'
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w
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of CFCs
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-
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w
Current u.s. Consumption
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29
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,
." ~
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<
O
Q,
.. .
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.. CJ c c .rn ... C %..
C .%
'W ... .Q, ..0 .."0 CJ <
Q
and Packaging to Reduce Use of CFCs
~ Q Q ...
... ...
.0
Q
4 a\
~
Q Q Q ...
-0 V
Q
-4'
Q Q ...
Q
Q
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Q
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Formulations
~ Ao
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..."'
'"'
!j..:~ ~..:% Q<%
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c.I~ %0 3~. 0"'..
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w-; N.Q
\J\J%
-~~ -c.I f-~~
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~r.. ~Q
I-'
w"' ~w.. '-I~:J ~<...
=
WJ . O~... >c.i > =
zo
3
~z
Ui'"Z ~C... CII~"' AoQ~
~(j~
>0 ~ o ~c"' OfUU i'"~
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:;G a ... ... c o 3 ~ 001 .,1 C < 1.0
o~ tJ-
~... z--
z o C.)t~ '""x C.)~ ~~ o~ C.)
. >.
\.0 ~c "'
z o
t uc u .0 .u c
.Q 000 C'"" ... >-\.0 ...0 rOo...
~ "' rn ~ Q
!:J' ~ 0 ~ ~
~ ~ " ~ c ... ... c o ~
-:; 0 ~ = ... .. = 0 ~
. ro1 ~ ~ < ~
r..(:) O(oJ ~< zu (oJ
>~ o
~
r..
>
"'
0 ~ ~
u~ ~u (oJ~ ~Q
~~ O~ >(oJ
~ u~ ~~
~: ~o
toJ"' z5 ~... ~"' o~ >~ ~
toJ .. ...
gu Qr.. OU ~r.. ~o
toJ"' (:)~
~
z
"'
~
o ...
z
u
z o
~(oJ (oJZ >... «
u~ r..z u~
o u
.a tn Eo U ~ Q O ~ Qo
on
Q GO .
00
I;
Current u.s. Consumption
o
0
...
~ 0
...o on
'0 G
C'O
C
0.. ~ Qo. C >00
~o
N 0
-U
'0 G
.'0..: U
-U..
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Q
N
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"'
V
I C..
G..
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a OG U~
0 tn
...CUG
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~G
r.JO..G...~
C I
OC.. U...~
0 ~
~ '0 I
..'OQo
00
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...0000000
O...N~... OOONOO
~
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0 ~
~ U
o 0 ...
-..U'O
: U
..0 G
~
.G U
~0000000 0000000
...V
N O
..
V
0...N~...
V
..'0 ..G G CG
e
e G
>
..G G
"' ...0...G\..0
000000
...~OOONOO
.., .o
..'...~O~r-..'~ ~oonr-..'r
0
G
e .0 0
..'...000
0
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~
Q
O
»
00 C
U
;J...C...
: ..a. G
.>0
C
...0..: fo Qo
Q.. r.J Q ~
)( r.J
U ,.j
of CFCs
31
32
Alternative
~U ..~
>0 ~
Ufo~ ~U.. ..0.,. m.QO
i m. ~
and
~~ 5..~.,.. O~... > >C to
U~ O~Z
Q
r-
...
r-
r-
.0 ~ Q
r..
. ...
~
0...
'a
-
..c .c.. ..
...~ 0...
.0
...~
0
Q,'
..0 ..~ .
i
.>
.8 !§ ...0... ,,0
."
c..
c0
U~ ~fo
...
.~
G
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~
..
~
,
G... ,Q,
~
.C.. J:OO fOO.
~
G
~
.
~
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..
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"
.
0
0
.~! >:
.0. ..
oe
S ~ ...~Q, 0 > .~.
.c fo
...
.~ >0 ~~ ..GG...
~
~ 0 .~~... ,
0
..0... .~
'aO. .~~
~OU ~O<
~.'a
'a
Q, e .'a
.=
...
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..CO .c
.>0.
0.
~
.~ .c ...~
~
..~ ...CO
..O.C G .c fo
Z
W fo O
Q,...
o..'a ~ G 'a
W fo O
Q,
0 ~ ~00.
Z ..a
,
Q
ng to Reduce Use of CFCs
Q
.
...
Q Q
N
.Q
. N
Q Q
.
" ,...
"0
~(j-
..=N
~...C ..'a
" 0". ...~... .C...
"... <.
~
"...'a
,e
C...O
...N. r
=
."Q N~..' c "'...
C
..,
.., ~ Q
.Q
..C
oU~r. m.o
Uu ar.!
'">0
!~ 00~... 0"'... >~...
QCZ 0 ~~ m.o r..
0
r.g.,. O..U tor. foCU
Formulations
"0 . ~ c ... .. c o ~
~ ~ ID < Eo
MN. ..,Q .. "'... ~~I ~ ~ ~ > CC... to... ~... U:
~ 0ut,Q r.J:... UO "'! ~0 U ~
to
0 ..OQQ.
~
U ~ Q 0
fo m. ...,.
U .,. r.1 Q
..."'a 001" ..=...
...~ ~ ..O...(j
C..-
~ '" U 0 Q
= to 0
m.
0 ~ m.
Current U.S. Consumption of CFCs
fndustry.
33
The aorosol sunmys by the Chemical Specialties Nanufacturtr's
bsociacion. Inc. ( C S U ) , the Can nPlur's Institute
(a) Precision Valve I
Corporrcion (POC). a t 4.conridor o n l y those aerosols of capacitias equal to or less t b a 50 cubic inchas. Butaxm lighter Rui& a r e not coruidared eo be
aarosolr: hourat. CFC refill r m F ~ vithin the s i z e limitation
are.
Alchoqh s o 1 aulpeious hrrr been granted for producu marketad both as cyltnd.rr md as aerosols, aa dofind rbaa, for tha purposes of this tepori, the cut-off fa the 50-cubic inch laml; Larger s i z e s a r e not considered in any detpil.
of PJunbQts bv h
t Produr+ TWQ
man dwmlopfag numbers for che column titlad "Product V o l w for A11 Vorsio~t (NU U n i t s ) , " only unfu of the a x a c t product type vera considered.
For axample. the "old Release Agenu' line refers eo releas. w e d in che production of p l u t i c md alaatouric matorialr. relawe agants used for coy -tal
agants for molds Figures for mold
(tin-bismuth) soldiers; cookie forming, ice-
cubo-m8kars. s o w c.ndlel.king, and other applications are not included, even though a small quaaticy of CFC is w a d in thesa a r a u .
Similarly, "Flying Insect Sprays for Afrcraft Fumigation" vere noc compared with the 106,lr00,000-unitoverall flying insect aerosol oarkec.
The use of flying insect sprays based on CFC formulations in commercial food preparation araas has dwindlad to a h s t nothing. Previous formulas have been rtplacad by water-based. hydrocarbon-propellad formulas, supplemented b y
anhydrous, hydrocarbon-propelled types w i n g cine-metering canisters actached to walls or posts. A major concern v u rastricting thesa sprays t o food handling areas. Employees were apc to spray bathrooms, dressing a r a w , and other unauthorized loeacions. The higher cost
was
a further concarn.
34 Alternative Formulations and Packaging to Reduce Use of CFCs
Althougt! meter-sprayed aerosols are noe exeqted. the new formulas have
been slov to replace &e meter-spray CFC-12 w a s because the mater valve supplier could not r e d l y produce r complex valve modification that vould spray 40-45 mg s h o u of che 1ov-d.nsity hydrocarbon formulas in place o f the u a u d 100-110 mg burru of th. suadrrd CFC compositionr (7).
T b *Xiliur]r Aoroaols' category inc1ud.r NO sub-groups: t h e flying insect spray (CFC-eype) axid elecaic/eleceronLc maintenance and tasting products (also C F C - q p a ) . Th. U.S. gournnunt ordars 1,500,000 10-Av.02.
2% Toxicants and 98% CFC-l2/11 once a year. Depending on insece populrcions during any y e u , from about 1,250,000 to the f u l l c m i U formulacod v i t h
L.500.000 units a r e releaad for shipment from the sole supplier. %as. formulas account for up to 1,020.000 lbr of CTCs. In Table 4. the remining 380,000 Lbr of CFCs a r e for eleceric/el~ctronic maineenmce activi-
ties around s o w , r r d u . radio. servomotor. computer, airplane controls. and ocher sensitive. costly, or sparking types of equipment.
The three classes of meter-spray inhalant aerosols used for medical purposes can bo defined as follows:
Metered-dose steroid human drugs for oral inhalation; Metered-dore steroid huaur drugs for nasal inhalacion; and
Metered-dose adrenergic bronchodilator human drugs for oral inhalation. Information from the H u k e l l Idoratories Division of DuPont shows che equivalence of nasally and orally inhaled drugs of the steroid types; chey are generally identical except for che plaseic nose or mouthpiece.
Current U.S. Consumption of CFCs
35
Table 4 of the present report only gives a total figure for all merereddose iubalrnt drugs.
usmi
The breakdown of these drugs is as follows:
Steroid drugs--oral
20 ( % units)
Steroid drugs--nasal Ergorrrine Tartrate vasoconstrictor drugs Bronchodilator drugs--oral
10
3
"
67
Tha Ergotmine Tartrate types represent less than one percent of CFCs in this category. This inhalant is a cranial vasoconstrictor. used for
nigraine and prodrome control. Two new metered-dose ethical drug products. a hair restorer (quick-breaking foam) and a curative pulmonary spray for bronchial pneunonia--so far only FDA-approved for AIDS patients--are reporred to contain CFC propellants.
The volumes for these products are unavailable.
since each is made by only one firm and the market results would be too revealing.
The hair restorer was released Ln 1988 ad the other vas condi-
tionally approved in early 1989. Additional details on metered-dose CFC-containing drug aerosol products appear in Appendix A.
Conversion of Ppynds of CFCs Uhen calculating aerosol units offered for sale from pounds of CFCs consumed (and vice-versa) it is seen t h a t : Aerosols are regulated as "delivering systems" for net weight purposes, and m s t therefore be filled to an average of 0.10 t o
0.25 Av.02. over labeled veight, according to size.
-
An
average of about 8%
ad filling process.
total
propellant is lost during the handling
This includes leakages, machine discharges,
and the 1.5 to 2 . 5 % of all aerosol units lost through process leakage. bad quality, testing. samples, pilferage, etc.
36 Alternative Formulations and Packaging to Reduce Use of CFCs
Noc all CFC aerosols are 1008 CFC.
Examples o f CFC percentage
1ovml.a fn othor producu are:
CFC Usage - (lbs) k t u d f i l l ( l b s ) x CFC Loss Factor x CFC Fraction
U.S.
-
Units
Mm FILIE&s OF CFC PRODUCTS
A substantial &r
of
marketers and
contract
fillers currenrly produce
hestimated 58 of all aerosols thrt s t i l l conuin C X - t y p e propellants.
Some of eluse ffrma are lirtad in Table 5 .
Current U.S. Consumption of CFCs
TABLE 5.
37
URKREUS AND F X W CUBRMTLY PRODUCING C F C - m -sou IN M E U.S..
Ir Il.nufrctur*
cow.
Qltsooicr. Inc. nillmr-lefphmren Chemical C-Q-Y
Acme
nS1 Four. Fault FLnbr
AudioTex 6 C d e c t t o Cbugmtte Cold Spray Hollfster JC Coneax 6 Crime-Solv Dalfen Fopr (vA&ld) U t (Chawing C \ n Ru.) Drain P o r n r (ObroleCe?) XmleuaGen (four items) H i r n u 62 (Fraezaae) LmccTo- Safe K0rop.x Foam (Vaginal) Lubrf Bond .%ce (Several types) Hate (Ocher types) Xold-Eue C S0Lir-Cl.m Quick Freezm Fraez-It. Lubrite, ecc. I n d u s t r i a l Fr882ant Freer'n Check C 70 PSI St e e 1-One Seal Afd 6 Spra-Drf Zapper (Personal R o t e e t i o n ) (Concrict Ffllmr) (Contract F i l l e r )
-
Dri-Slid.
(Contract F f l l e r ) Electro-Fraez. Falcon, e t c . F h v Flnder Benvenue Clobm Spray (For endoscopic wrk) h k i k i . Voltex C Term-Ouc
Tuckat, CA Iiauppauge, ANY D m b u r y , (3
A a r a w - P a c i f L e capany Crarm Industrial Prodaictr
san b m d r o . C h Hebron. IL
C0lp-Y C.C. Electronics Division
Bockford. I L
colpurl,
ut0801 b e lbdiC8l
Productr co. Hollfrrmr l b d i c a l R o d u c t r -son Laboratorier, f n c . S C . V r n - ~ lC l h d u l corp. Johnson rad J o b o n . Inc. Avmor, Limited nfrvick I ~ + r i e s Inc. , B.1murC.n Manufacturing Co. T.ch Spray, Inc. h b i S ChOdCAlS, h C . Holland-Rancor Co.. Inc. Electrofilm. Inc. smith 6 wesson co. Clnmral Ordinance Equip. Co. Ch.p-PJr. L n c . Sentry Chemical Company W o r k Electronic P r o d u c t s Rolau: The Supply corp. Chemlronfcs. Inc. Madison Bionics, Inc. O r b I n d u s t r i e s , fnc. s a h q d Security colpany b r o s o l Systems, Inc. Chu. Products, Inc. Drl-Slid., Inc. Armstrong k b o r a t o r i e s . Inc. Falcon Engineering Co. h r i c a n Cas C Chemical Co. Bmnvenue h b o r a t o r l e s . Cnc. Globe Hedf u l Instruments ,
Neodmssr,
KS
I m i n e , CA Chicago. IL Erie. PA M t . Vernon, NY Raritan. NJ Montroal (Canada) Carlsudt, NJ Dellno. HN Amarillo, TX Cincinnati, OH Trenton, NJ Vanmncia, CA Springfield. M S p r i n g f i e l d , .XA Winchester, 5N Stone Mountain. CA Sarasota. FL Lake Geneva, UI Hauppauge, NY Franklin Park, IL Upland, PA Hnrleysville, PA Macedonia. OH Mayvood. I L Freemont, SI Uest Roxbuzy. MA Mountainside, YJ Northvala, NJ Bcdford, OH C l a a m o t c r . FL
I=. Wki Electronics Company
aInhalant drug producers are not l i s t e d .
Hauula. Hawaii
4. Suggested Alternative Formulations for Exempted and Excluded CFC Aerosols
The CFC p r o p e l l m u in e x q c e d and excluded a e r o s o l s a r e c u r r e n t l y p r e f e r r e d f o r a variety of reasons.
Such reasons include their nonflan-
mability, high p u r i t y . d q u e s o l v e n t c h a r a c t e r i s t i c s (CFC-113 i n p a r t i c u l a r ) , o r the fact chat they ha-
bean made an e s s e n t i a l p u t of New Drug Amendments
(NDAs) f o r p h r m r c e u t i c a l meter-spray a e r o s o l products. O t h e r propdlants or b l e d
MY e x h i b i t
Since
s o w o f these p r o p e r t i e s .
1983, a set of f o u r alternatives t o CFCs has bean c o m e r c i a l i z e d , and another set
of f o u r is expected t o coma onco the market i n 1992 o r 1993 i f t h e r e s u l t s
of t o x i c o l o g i c r l t e s t i n g programs continue t o b e favorable.
The p h y s i c a l
p r o p e r t i e s o f the aighc a l t e r n a t i v e s a r e summarized in Table 6 .
All the
p r e s e n t l y a v a i l a b l e a l t e r n a c i v e p r o p e l l a n t s a r e gases a t room temperature.
-
o r l o v e r ; t h e r e f o r e , none can be considered a direcr-
Boiling p o i n t s a r e 14'F
replacement f o r CFC-11 (B.P.
73.3.F)
o r CFC-113 (B.P.
-
about LZO'F),
which
a r e liquids a t room temperaeures. Although HCFC-22 is nonflaimaable and is commercially a v a i l a b l e , t e r a t o genic u n c e r t a i n t y has discouraged marketers of metered-dose pharmaceutical Lnhalanc a e r o s o l sprays.
The extreme solvene a c t i v i r y of dimethyl e t h e r is zn
additional concern f o r those firms marketing drug products in s o l i d suspension
forms because of Oscvald Ripening e f f e c t s that change p a r t i c l e sirs d i s t r i b u tions. In t h i s section.
No
o r more formulation options will be presented for a
number of produccs that c u r r e n t l y use r e g u l a t e d CFCs.
Some have a r e l a t i v e l y
g r e a t e r p o t e n t i a l f o r s t r a t o s p h e r i c ozone d e p l e t i o n than o t h e r s .
38
Although the
~ ~ j ~ ~ a. O ~ a.
~ O cn ~ ~ < ~ ... ~ < ~ ~ ~ ~ < ~ ~ ~ ~ r.. ~ ~ ~ ... cn cn O a.
Q ~ ~ z toI ~ ~ u
'0 toI ~ ~ < ~
U
N ...= IU-o U U r.. =
r.. U I r.. U ... ... U
.N
o
.. ~ U
U
~ U =
r
I U,V
;9 U o I V... ..-0 = U
.., N ...=
...u I U r.. U =
.. =
~ .. .., = ...U... I I -0 U ..N r.. r.. = U
.U
~ N
... = U r.. = U
..-0
O =
U -..,
... r.. U = U N ...N
,
-0
...I... I ...~ U r.. N r.. ...I U U = U
~ N ." ...I..' UI... r.. = I ...~ >0 ~.c a..
.c
...r.I Q N N I U r.. U =
. ."
..
." N-
. ...~
. N-o
~
...I
...I..'
...,
~
-a. Q.o -..,
0'
~ >~
0'
~ >~
Q.. -Q
r.. ~ e W
r
0 r..
U ..~
~ a.
~ Q o
r..
.c Z
.c Z
... ...
" O
.c Z
.c Z
r.. Z
." ...
r..
."
...
... ...
." ,
..,
2
Suggested Alternative
N ...Z
... ..,
~
0
...Z I
...
, .
...
>0
r..
.. C
...>0..
.Z I
0
OC "'...
~ ~= ...
... .~...o I O'~ ~Cr.I
~ r.I
...~~ r..~-
i
~ r..
0' C
0. ~-
'0 .~ .. ~ e ...Z .. ..I .
I .Z
Formulations
~ 0 ... .. =' ~
~
.. ~ ..
r.. Z
Z
E . >
O
... ~
::: 4 0
<
39
40
Alternative Formulations and Packaging to Reduce Use of CFCs
aerosol industry has received surple amounts of most 'future tive propellants,' product properties u of those m t e r i d s in any
fUW8
possible alterna-
t be estimated when proposing the use
aeroaol forrrlations.
DISCUSSION OF ALZEUUTIVE CFC FORMJUTIONS
This section ulll preaent dterrutives to CFC aerosol forwdations by 1) dlscurslng tha currently exempted rrd excludod products irdividurlly; 2) offering gmn8ra.L c o w n t s ; 3 ) suggesting alterrutive formalas; and G) drawing conclusions. Factors that were cansidered when developing the alternative formulations includ. the following: Production of sprays with desired particle size distribution;
. v
Control of flrubility; Precautionary use of questionable solvents, such as methylene chloride:
-
changes in anticipated use patterns; Maintenance of dispenser and organoleptic stabilities: Cost of altenutive formulations;
Availability of the alternative. including Toxic Substance Control A c t (TSCA) considerations;
.
Pressure l i d c a t i o n s ; Roducr u t i l i t y or efficacy for intended uses;
Suggested Alternative Formulations
41
Toxicological factors; md Spray rate and -0-up
rate optbization.
Thoso products u a currently formulated from
UI
approxfmately 3 to St
b u m of lecfthfn, hmctioorl sflfconr, or othor material dissolved in a CFCProduct puriv, propellant velatiliCy, and nonflammbilicy u e \up properties. T h p l u t i u and e l u t o n r r bofng w l d a d should not be
ll/CFC-12 blend.
contaminated vith such Mimovn entities as solvontr or inhibitors. The base should be delfvered to the mold surface v i t h as l f t t l o Loss (bounce) as possible.
CFC-11 currently pr0v-id.r the desfrad high-transfer efficiency
Tva representativa CrC-buod fornrlu are PI follows:
I.
38 578 a 8
11.
58 658 25a 58
h c i t h i n (Soy Bean Source)
m-11 m-12
Sflicono (Dimethacone CFC-11
--
1000 centistokes)
CX-12
Propane A-108
Both are inainsicrlly nonflamable. Uhen traces of inhibitors (such u nftromthano or 1.4-dioxane) are nor a problem. am optional formslation such as the following may be suggesKed:
111.
38 27t 58
398 268
h c i t h f n (Soy Bean Source) Inhibited ifethylene Chloride Ethanol Anhydrous (Liquid denaturants only) HCFC-142b HCFC-22
-
-
The inclusion of methylano chloride is based on studies by Dow Chemical Company. et.al. shoving thrc the single poricive mucagenicfcy s m d y vas (ani4)species specific and thac the compound does not affect humans.
The tocal
42
Alternative Formulations and Packaging to Reduce Use of CFCs
formulation would have a pressure of about 48 psig at 70'F
I t would have a density of about 1.19 g/mL at 70'F,
(air-free basis).
m m i n g that only about
801 of tha present vaighe of there products could be placed in the filled can
If wChylelu chloride is comaIdared uarcc.pCable from the standpoint coriwlog or rolvmcy. It could bo r a p b e d by 1.1.1-trichloroethane
-
of
krhibtted (4).u fn cha follovfiy formlation:
Iv.
3t 37-
36t 241
hcithln (Soy Barn Sourc.) l , l , l - T r l c h l o r o e ~ a Inhibited HCFC-142b Ha-22
-
This would bring approximately 31 of decomposition inhibitors (as free-radical chain braakerr. such u n i t r o m a . etc.) into the formula, sfnce they are necessary to counter the self-destruction of the 1.1.1-trichloroethane. The bailing point of 1,l.l-trlchloroethPn. (about 152.F)
is high enough
that n u l l amounts could remain for a short t h e on the die surfaces, depend-
fng on conditiona. and cause mi& in che malded part. The most costly formulation must await the availability of HCFC-123
OK
HCFC-141b. The fornulacion could be as follovs: V.
3t 65t 32t
h c i t h i n (Soy Bean Source) HCFC-123 (B.P. 82'F) HCFC-22 0
If a preference davelops for HCFC-141b ( n a m a b l e ) over HCFC-123 because of price or toxicology, a f i n d formdo option can be considered: VI.
3t 14t 50t 33\
Lecithin (Soy Bean Source) HCFC-123 (B.P. 82'F) HCFC-141b (B.P. 9O'F) HCFC-22 0
0
43
Suggested Alternative Formulations
Formulas V and VI would ham pressures and liquid densities comparable c o those of the present products. Solvency, for tho bases, vould be excellent Formula VI could be checkad for f l e i l i t y , as should the possibility o f replacing the 14a HCFC-123 Vith 148 d d f C i O M l HCFC-Mlb, should this be &sired.
Aerosol lubricants
MY
assumo mnurous forma, according to the end use.
€or example. a lubricant for screen doors. sliding r l d n u m doors. door locks and hinges could consist of tho following: .SO*
VII.
1% S#
Specialty Lubricant Blend 1,l.l-Trichloroethane Inhibited (4) Carbon Dioxide
-
This lubricant could also bo dispensed through a capillary extension rube up to 8 inches long fitted into the actuator orifice.
Electrical applfcatiom. as for motors, trarufonners. svitches. and relays, generally require a nonflaDnable product and
d
spray delivery.
This
1s especially c n m of aerosols, vhere large-scale, spark-producing equipment, such as che commutator ring of a 250 HP motor or dynamo, must be lubricaisd. CFCs have been used in these lubricants to ensure that the combustibi1i:y che specialty o i l itself is suppressed.
Some
of these products are also
of used
in r o o m or areas vhere smoking and the use of flammable or combustible solvents are prohibited.
VIII.
5 65 30
--
158 508 358
The composition of one such product follovs: Specialty Lubricant Blend CFC-11 CFC-12
The use of hydrocarbons or ocher flammable propellants is contraindicared for electrical equipment because sparks of sufficient energy (over 0.2 kilojoules) can lgnite flamable-range mixtures of chase gases and air, harming bath operator and equLpmenc.
I n some insrances, spark streams or
electrical resistance may act to scrongly heat a surface, causing combustible
44
Alternative Formulations and Packaging to Reduce Use of CFCs
solvents t o heat up beyond t h e i r f l a a h point, and f l m b l e solvents t o heac up beyond t h d r auto-ignition point.
Pinally, o u f l y d.coqmsed b ~ l o g o ~ t esolvenu d m y produce hydrogen chloride. phosgezm, .ad other activa g u e s that can u t corrosively o n hot coptact polxtts. resistotr. etc.
T b CPCr (especially CFC-12 and CFC-114) are
hfghly resistaxat t o pyrolysis.
In elm e l e c u o n i c r 'area. sprays wt be n o n f l d l e because of equipmoot or d r o r r w n t r e s u i c t i o a r ; pyrolytic corrosion is also a concern. of
One
several producu is formulatad u follovs:
Ix.
Sa 6%
Specialty Lubricant Blend CFC-113
30r
CFC-12
The CFC-113 c a r r i e s the lubricant t o the surface to be t r e a t a d , alloving a dnha rrouat t o c o n t d n a t e the a i r . greasing, flushing action. reaming -anted
A t the a-
tima i t exorts a de-
vapor fluxer residues and d u s t s .
Several a l t e r n a t i v e s t o CFC products are a v 8 i l a b h .
F i r s t , when motors.
coaputer boards, and similar i t e m a r e not e l e c t r i c a l l y connected, and unless the added solvency of 1.1.1-trichloroethane (4) is a problem, Formula VI1 can be used in conjunction with a meter-spray valve t h a t w i l l reduce the amount o f
Lubricant sprayed out. 'shots'
For example. a 6 Av.02. can be ma&
to give abouc 1700
of about 100 mg each.
For greater u n i f o r d t y of the spray p a t t e r n during package life, anocher formula could be considored:
X.
60r 121 28r
Specialty Lubrlcant Blend 1.1.1-Trichloroethane Inhibfted (4) HCFC-22
-
Suggested Alternative Formulations
45
If the presence of l,l,l-trichloroeth.n. creates a problem, Khe following more costly mter-spray option should be useful in a ‘WT Speclflcation 24’ u r o s o l can:
n.
68e 32a
S p . c i a l e J r Lubricant B l e d
rirrC-22
Finally, if a product compuable ea FornrLa X is naadad. a counterpart cha greatest challenge. Zba best candidate is Khs
t o CFC-113 vi11 present
follovin(l: X I 1.
5t
Specialty Lubricant Blend HCFC-LLU HCFC-22
721 231
CC1,F)
~ of HCFC-16lb (q-CClzF) a d CFC-113 (CClFZThe ~ C ~ U C C I . Ushi1uiti.s suggest Choy may possess a sfnihr solomcy potential. Formula X I 1 is
of marginally acceptable f l d i l f t y . This caa be corrected. if nacessarj. by using additional HCFC-22. or by using a moter-spray valve. I n time, Khs replacamant of HCFC-22 w i t h HFC-1360 could result in a lover pressure and a lovar concencration of chlorine i n Formula XII. for
Pfll
These produces ~t
be nod-ble
and leave only a Food Grade ((Cener-
ally Recognized As S a f e (CRAS)-Listed] residue on surfaces contacted by che pharmaceutical item. XIII.
2.01 0.5a
2.51 70.01 25.01
Folloving is a typical formula:
Lecithin (Sop Bean Source) Sorbitan Trioleate Ethanol Anhydrous (Pure Grain Spirits) CFC-113 (Especially purlfled) CFC-12
-
Since a high-purity, nonflamabla. volatile liquid is rcqulred. which can currencly only be mat by CFC-113, a 32t reduction (ln ozone depletion potential) can be made by using the folloving formula:
46 Alternative Formulations and Packaging to Reduce Use of CFCs
m.
2.01 0.51 2.51 65.01 10.OI 20.01
Lecithin (Soy Bean Source) Sorbitan T r i o l e o t e E-1 Anhydrous CX-113 HCFC-142b HCFC-22'
-
I f md uh.p HCFC-L23 b e c o n s c o w r c i a l l y a v a i l a b l e , tho formulation could then ba.rmvi8.d t o tha following:
m.
2.01 0.51 2.51 77.01 18.01
If HCFC-123 dKeL7¶atiP..
m.
doas
-
not becoma c o n u r c i a l l y a v a i l a b l e , t h e following
nodlamable formula can be o f f e r e d : 2.Oa
.0.51 2.51 55.01 30.01 10.01
ul-ers.
LmciKhill (Soy &an Soure.) Sorbi tan T r i o l a a t e Ethanol Anhydrous (Pura Grain S p i r i t s ) HCFC-123 HCFC-22
h c i t h f n (Soy B e a n Source) Sorbitan Trioleate Ethanol.- Anhydrous (Pure Grain S p i r i t s ) HCFC-14lb HCFC-124 HCFC-22 f o r E l e c w E l e c t r o ni c Eauiurnenc
-su D
The s o l v e n t - c l e a n e r s and dusters f o r d e l i c a t e e l e c t r i c and e l e c t r o n i c items consist almost uniformly of t h e following:
m1.
751 251
CFC-113 CFC-12
Except f o r the inclusion of approximaKely 1 t o 31 a c t f v e i n g r c d i e n c s , various coacfng sprays a r e s f m i l a r l y formulacad.
CFC-113 fa unfque because of its nonflammability, r e l a t i v e v o l a c i l i c y . high puricy, compatibilicy with m a t e r i a l s of c i r c u i t - b o a r d and ocher conscruct i o n s . and f o r f u s e l e c t i v e s o l v e n t a c t i o n o n g r e a s e s . oils, and s o l d e r by-
Suggested Alternative Formulations
produco.
I n so-
47
fnrtmces. combinations of o t h e r s o l v e n t s may s u f f i c e , such
u l.l.l-trichloroeth.lu,
f o l l o w d by d o i o n i t a d v a t e r and then h e a t lamps.
Houever, the b e s t Lowdiate course of accion m y be t o r a p l a c a t h e CFC-12 (and
perhaps a p u t of the CFC-113) w i t h o t h e r p r o p e l l a n t s , u shorn belov:
m x x. -
Hx.
Crc-113
828 181 or
IICFC-22
708 168
CFC-113 HCFC-142b HGFC-22
148
If HCFC-lZ3 b e c o w s co-rcially
a v a i l a b l e , this nonflammable l i q u i d
could be f o d r t e d as follows: XI.
838
178
HCFC-123 HCFC-22
A l t e r n a t i v e l y , the following replacement f o d a can be o f f e r e d : XXI.
608 308 108
HCFC-141b HCFC-123 HCFC-22
A f i n a l a l t e r n a t i v e takes advantage of t h e - h i g h - p r e s s u r e azeocrope o f
HCFC-2Z/Ptopano (68:32). which h u a p r e s s u r e of about 135 p s i g at 70'F
and
t h e r e f o r e cannot be added t o a e r o s o l cans except as i n d i v i d u a l i n g r e d i e n c s .
The bland is fllmrble, b u t it can be rendered n o n f l m b l e by the use o f
HCFC-123; f o r example:
=I.
87.008 4.168 8.84
HCFC-123 Propane A-108
HCFC-22
48
Alternative Formulations and Packaging to Reduce Use of CFCs
This c8tegory nou
accouau f o r about 4
Pillion pounds of CFCs a year in
the U.S. (1% of dl CFC a e r o s o l w a s ) and inc1ud.r approximately 70% of the 152 nillion CFC urosol product d U s o l d d t h u e producU is V costly p r o p o l h c s .
l y .
The d o l l a r v a l u e o f
high, ~ all&& latitudm fn reformulating them v i c h more Th. avorage canister holds 16.0 g. o r about 0 . 5 6 A V . O Z .
O
'Ihr estimated f o d u of f i n high-oolrru Mtered-dose inhalant drug (MDDID)
products are sborm fa Table 7 .
Tho u l t k . t a c o m n r r i o n of the v a r i o u s 'Mtered-doSe inhalant drugs"
(mIDs) t o
non-CFC f o d a t i o n s r e p r e s e n t s the g r e a t e s t f n d i v f d u a l challenge of dl u r o s o l changeovers. IpdLutx$ contacts r e p e a t e d l y assert that LWID is a l i f e - p r e s e m m r f o r thousands of dependent users.
Of the p r e s e n t l y a v a i l a b l e "CFC alternative p r o p e l l m u " only HCFC-22 is The ~ d l d l aet t r i b u t e is highly d e s i r e d because most .WID
w n f l e l e .
users a r e heavy smokmrs aad may be holdlag cigarettes v h i l e u s i n g the product.
(The importance of chis a s p e c t fa argurble.) However. ocher problems v i t h H a - 2 2 are l i s t e d belov: a.
Teratogmnfcirp
HCFC-22 inhaled ac 50.000.ppm f o r GO hours per veek by pregnant rats in che middle t r i m e s t e r r e s u l t e d i n 0.15% anophthalria aad 0.05% cryptophchalmia; Imperial Chemical I n d u s t r i e s , Ltd. (ICI) c o n r i d e r s &ere f i n d i n g s t o be s t a t i s t i c a l l y significant.
b.
O t h e r Toxicological Aspects
Inhalation toxicology studies beyond chose nov compleced would be r e q u i r e d f o r indudtry apptovsl. the p r e s e n t
array of r e s u l t s .
The FDA is s a t f s f i e d v i c h
Suggested Alternative Formulations
bgr.dieats
D a 6 Sorbltm hiolorta Ethx101 Abrolute
-
Brrolrho-
Broncho-
Broncho-
dilator
dilator
dLhtor
Steroid
Steroid
0.147
0.714
0.24
0.386
0.833
1.000
--
1.000
1.00 1.00
--
-e
--
m-11
29-00
15.000
24.571
m-12
78.00
69.000
49,144
15.000
24.571
cn-114
49
--
1.00
__
.-
20.000
98.76
5a.6i(r
--
20.000
50 Alternative Formulations and Packaging to Reduce Use of CFCs
I h e drugs now used f o r adrenergic bronchodilator and c o r -
t i c o a t e r o i d therapy a r e themselves t e r a t o g e n i c t o animals, and
them is a concern chat one t e r a t o g e n (HCFC-22) could r e i n f o r c e the t e r a t o g e n i c a c t i v i t y of another ( t h e d r u g s ) .
Thus,
t e r a e o g d c t e s t i n g of .ny proposed new-propellant products varld ba Medod.
'Lh. greater solnncy--thus mucosal and tisstu permeation--of
HCFC-22 could cause a more concentrated drug tide t o be d
a
d through the p r e - a l v e o l a r t u b e s , l e a d i n g t o p o s s i b l e
t o x i c o l o g i c a l and 'toxic c.
shock'
effects.
Reduced Liquid-phase Density
A predominrntly HCFC-22 product would be about 10 to 15% l o v e r
Ln &asity than the usual MDID items; e . g . , 1.2 g / d . compared with 1.6 g/mL. This could cause f a s t e r s e t t l i n g o f t h e s o l i d drug in the pdmr d i s p e r s i o n formulas t h a t make up about 90%
of che industry s a l e s volume.
Sfnce t h e meter-spray valve is v o l u m e t r i c a l l y based, about 10 to 1%
higher percent by weight l e v e l s of the drug and
e x c i p i e n t s would be required.
Likewise, l a b e l e d n e t veighc
would have t o be reduced o r converted t o l a b e l e d n e t volume. d.
Increased Product Pressure
The pressure of HCFC-22 fs 297 p s i g a t 130'F;
CFC-12 is 180 p s i g a t 130'F.
whereas, t h a t o f
Under Title 69 of the Code of
Federal Regulations (CFR) , the Department of T r a n s p o r t a t i o n r e g u l a t e s the i n t e r s t a t e shipment of most a e r o s o l s ( S e c t i o n s 173.306(a) and 173.1200(8)].
Most a e r o s o l s a r e not permitted
t o have pressures exceeding 180 p s i g a t 130'F,
f o r these products are c o n s t r u c t e d accordingly. c o n t a i n e r s l a r g e r chan 118.2 MI. c a p a c i t y . )
and c o n t a i n e r s (Applies to
Suggested Alternative Formulations
51
Unless &e HCFC-22 p r e s s u r e is s i g n i f i c a n t l y reduced by che use of suppress.nt type p r o p e l l m t s (such as HCFC-l42b), .ahraced lukage rates and o t h e r d o t e r r a n t f a c t o r s n i g h t dovebp.
H a - 2 2 is a s u b s t a n t i a l l y b e t t e r solvent than CFC-11, CFC-12
or CFC-114, and could d i s s o l v e o r p a r t l y d i s s o l v e c e r t a i n micronized m i c r o c r y s e a l l i n e drugs. I n the l a t t e r c a s e , unvlrrced crystal grovth could occur as the l a r g e r c r y s t a l s grov at the expense of &e saaller ones. This could eventua l l y reduce d a l f v e r y o f the product t o the s u b - c i l i a l p u l locly
f.
regions o r even cause meter-spray valve blockage.
D i f f i c u l t i e s in Refornulation
HCFC-22 has been r e p o r t e d by 3n (Rfker k b o r a t o r y ) and o t h e r drug houses t o complicaee product redevelopment. A b e t t e r approach n i g h t be f o m u l a s such as t h e
=XI.
Drug Sorbitan Trioleate CFC- 11 HCFC- 142b HCFC 22
-
Resswe :
Flamability: Density:
-
following:
0.50% 1.001
13.508 51.001 34.008
61 p s i g 7O'F ( a i r - f r e e ) N o n f l m b le* 1.19 g/mL a t 7O'F
t h e slurrying l i q u i d and the p r o p e l l a n t blend a r e nonflammable i n a i r .
*Eo&
52
Alternative Formulations and Packaging to Reduce Use of CFCs
or onm baaed
09
mp.
HFC-13k aa the main propellant, such as the folloving: DwJ
0.501
Sorbitan Trioleata m-L G l b cpc-11 m 4 3 4 . a
1.001 9. 591 4.001 75.001
HcpE-l24
10.001
Est. Prossure:
70.5 paig at 70'8 180 paig at 130'F NOUfl.lubl.* 1.20 g/rL at 70'P
Fl.ubilitp L t . DeMity:
(air free) (air free)
-
+Both tho slurrying liquid and ehe propellant blend are non.1ip air.
Follovfry a r e smvmral raaaona to dovdop a formula brsed on HFC-13Ga as rh. m d n propollaat:
a.
XFC-13h tooiu e x t r a r l y promising u a refrigeration/air con-
ditioning fluid a d aeroaol propellant of exceptionally lov toxicicy. It also hrr no C1 or Br atoms. and cherefora does no'c a f f e c t tho stratospheric OZON layer. b.
KFC-13tr 0.7 eventurlly bo produced in IIUP.~OUS countries for refrigeration/air conditioning uses, so that vorldvide availabi1ic.r should not bo a problu.
E.
The pressure of the system is comparable to che pressures of the current MDIDs:
at 70'F d.
70.5 psig at 70'F
compares co 52 to 70.7 psis
The solvent activity of HFC-13h is comparable to that of the CFC-
l2 e.
..I..
(air free).
MY
fn use for M U D S .
The density of Formula IUXV. while only about 8 5 1 thac of the usual MDID should not pose significant formulation problems.
Suggested Alternative Formulations
53
To a d n u i n the sap. liquid vohme (and c a n i s t e r s i z e ) and the same m u b a r of doses p e r package, ehe drug c o n t e n t vould have t o be
incrmued by about 188 (v/v) f o r t h m sasa meter-spray dosage m l m ~ .and the net. weight w u l d have t o be d s c r m u e d by 15%.
Short of r r t a l a f n g currmnt CFC formulu, there a r e no o p t i o n s f o r foroulrtlng
mID
products at cb.ir c u r r e n t density levmls of 1.3b
t o 1.40 g/pt a t 7Q.F. except, p o r s f b l y . f o r using Freon C-318 (perfluorocyclobuutu:
C,F,)--a
lov-prmssure food-grade p r o p e l l a n t
c o m m r c i o l i z a d d u r i n g the 1970s b u t nov discontinuad because o f its
high c o s t , abseace of marbe. md o t h e r f a c t o r s .
W o n t has been
urged t o re-eXPPLM the artfts of this p r o p e l l a n t , vhich h a s t h e d s i r a b b l e propmrty of very
f.
LOW
solvency.
The h i g h e s t - p r e s s u r e p r o p e l l a n t fs prmsent i n the l a r g e s t p c r -
This is e q u i v a l e n t t o the presene KDID formulas, vhere I t allows the product t o toleratm minor gas seepages ( n f c r o - l e a k a g e ) , vhich
cencage.
the percentage o f CFC-12 p r e s e n t is from about SO eo 9 8 . occur i n a l l a e r o s o l s , b u t they have SMll
O t h e r importanc Formula
1.
mort s i g n i f i c a n t e f f e c t s on
d i s p e n s e r s w i t h l i m i t e d amounts of propellanc.
xxfv c o n s i d e r a t i o m a r e presented belov:
HCFC-LLlb (very s l i g h t l y flammable; B.P.
-
90.F)
is very lov i n
t o x i c i t y ( i n t e s t i n g done t o dace) and is the primary s l u r r y i n g agent. Becaura of the s l i g h t flammabU.ty. it is necessary t o add noc more
than 4 . 0 0 8 CFC-11 (B.P.
-
74'F)
to produce a nonflammable s o l u c i o n .
This approach has t h e following problems:
CFC-11 is
a c o n e r o l l e d s t r a t o s p h e r i c ozone deplecion a g e n t .
54
Alternative Formulations and Packaging to Reduce Use of CFCs
I t vould complicato tho NDA process i f u l t i m a t e reformulacion
M o t d i f f o r e n t procossing tochniquos bocomo a p p r o p r i a t e in M 'openings' are more c o s t l y than one.) tho t u w e . (Tvo N
Us.
a blood of HCFC-123 and HCFC-14lb that is shown t o be
m d l . r u b l e and coauins tho highost p r a c t i c a l l e v e l of s l i g h t l y f l d l o HCFC-141b t o minimizo pulmonary exposures t o HCFC-123 (Fornula XXVI).
Us.
1001 s l i g h t l y f l d l e HCFC-141b as tho slurrying agent.
takin5 nmcorsaq precautions t o minimize tho p o s s i b i l i c y of
fir. &/or
-
explosion ( F o d r XXDII).
P.pl.co CFC-11 w i t h CFC-113 (Formula XXPIII) f o r t h e following rouons: Its r e l a t i v o osono-depletion p o t e n t i a l is 80% t h a t of
CFC-11 (9).
CFC-113 is loss v o l a t i l e than CFC-11 and can be handled
in drum r a t h e r than c y l i n d e r s . CFC-113's n o n f l d i l i t y i n blends is s i m i l a r t o t h a c o f CFC-11, r e f l e c t i n g its lover volatility and higher
molecular v.i@t. 2.
Tho *trim propellant' p o r t i o n is 75 p a r t s o f HFC-136a and 10 parcs HCFC-lZ* (Formulas ZCIV through XXVII). Tho lacter is added t o t e duce tho vapor p r e s s u r e of the HFC-134a i n t o the usual 'WT SpcciThis ficacion 2Q' prossure range of less than 180 p s i g a t 130'F. me-
Ehrt tho usual aluminum o r s t a i n l e s s steel c a n i s t e r s will
Suggested Alternative Formulations 55
suffice. However, for containers of lass than 4 fluid ounces
(118.2
a), thls
is not a requirement.
Using s u a i g h c HFC-134. ir another option. if tho extra pressure The additional pressure would be about 5 psi unb. uc.tod. 8f
'Ib. COUSOqUOllCOS fOllOV:
d 12 p8i af 130'F.
70'P
A rtatfrtieal reductioa o f
HCFC
02-
d q h c i o n by removing
th. EFC-124 (Fonrulr XX). &duction
in f o d a complexity by elfminnting one ingredient
(Foorpulr XXX). 8.trfev of pressure-rorfrtaat qualities
of tho presently used Tho supplier would have to for products w i t h vapor pressures to
cmfrterr and vials.
8.l-
gurr.nt08 h i s safe uae
about 192 psig (130'F)
air free, and/or about 210 psig (130.3
if amosphericrlly clinched. Revfew of the Department of Transportation (DOT) position. ltro pages from tho present tariff containing replacions f o r
compressed gases in dispensers of 7.5 cubic inches ( L . 0 fluid
ounces. or 118.3 ml) or lass appear in Appendix B o f chis report.
Pressure limitations are not described.
p r a S S ~ ~ i t 8vi& d
Products
propane (unsuppressed) are known to be sold
in scodrrd a l d n u m containors for nail guns and other uses. Aa currently produced, chay have pressures o f abouc 123 p s i g at 70'F
and 278 psig at 130'F--vith atmospheric crimps.
Table 8 sunauizes the above &tailed
discussion of the various f o r (The pressure
mulas, compares their proporties, and gives preference ratings.
data in Table 8 are psi at 130';
09
an air-free basis.
For 20'Hg'
vacuum crimping, add 7
for atnospheric crimping add 22 psi at 130.8.)
The preference ratings in Table 8 assup. that pharmaceutical firms and their fillers cannot dilucencs having reasonably handle the filling of slurries made w i t h fl-ble
56 Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 8 .
FornuLa m e r :
-
COMPARISON OF RECOMSNDED M)ID FORMWAS
m.
XXVI.
75.0 10.0
Rarrure (70'F paig) 71 Pressure (130'F paig) 180 Density g/mL 70' 1.20 Slurry F 1 d l e P uo
-
0.046
XXV'III.
XXIX.
.m.
0.5
0.5
0.5
0.5
1.0
1.0
1.0
1.0
1.0
1.0
13.5
6.5 7.0
9.5
6.5 7.0
4.0
-
XXVII.
0.5 9.5
HCFC 14lb CFC-11 CFC 113 IIFC-13& XCFC-124
S t r a t . 0,
xv.
75.0 10.0
5.3 1.5
9.0
0.5
4.0
4.5 7'5.0
75.0 10.0
66.7 25.0
69 175
180
85.0
85.0
10.0
71
71
180
180
1.19
1.19 Border
1.21
1.20
Uo
Border
NO
0.007
0.007
0.024
0.042
76
76
192 1.18 No
192 1.17 Border
71
0.043 O.OO&
Depleeion Potantfa).
-
(CTC-11
1-00)
(1 is Highest: 7 is L o w e s t )
1 I
If Toxicity Ekcing of HCFC-123 1s Equal t o or Becter That o f CFC-u
I f T o x i c i t y Racing of XCFC-123 is S i g n i f i c a n t l y Worse i h a n That o f CFC-11
xxv. xxx.
XXVII.
XXPII.
xxx.
XXVI .
xxn.
XXIV. XXVIII.
=MIX.
XXIV .
XXVI . XXVIII.
xxv.
Suggested Alternative Formulations
flash pofntr b e l o w room temperature.
57
Othervise, slurries of predominancly
HCFC-141b would be recorundad.
-
Finally, it is r e c o u d d eh.c the UDID &orlopaant chemists conLn areas. u f l l r u t r a t e d by the f o d u shorn in T a b l e 9.
castrate
XCFC-lZ4 is preferred ovmr presently availrble HCFC-l42b, because the lattar is slightly f l i n u b l e md tha ability of HFC-134r to suppress this
nrPvbi1ity is uukLovn. Uhen calculaeing che seratospheric
OZOM
daplecion values f n Table 8 , in
-
the absence of complete data, the r e l a t i v e &plation potential of the various
HCFC matarids v u calculated as 0.03 (baaed on k - 1 1
1.00).
The ozone
dapletion valuer of HCFC-22 and HCFC-142b are about 0.05 and 0 . 0 3 , respec-
tively. Using the 4.0 million-pound & M S ~ ~ Cuse level (1988) of CFC propellmta as a b a s i s , Table 10 rhous the calculrtad ozone riaplation levels of the e
~
UDID , formulas rankad highest. About 101 of the HDID aerosol volume consists o f aerosols in which the
drag i t e m is in solution irutaod of in the usual microcryscalline suspension.
In there formulas, if the drug can be dissolved in che concantrate (such as ethanol) and a l l halogenaced ingredients added as a nonflammable propellanr.
then formulation p o r s i b f l i t i e s become easier. the formulas shovn in
Table 11.
The transition is suggesred by
58
Alternative Formulations and Packaging to Reduce Use of CFCs
TULE 9. FINAL RECOkMENDED HDID FORMnA PROTOTYPE
Em.
Ic,lPula.
X
n
g
~ (1) ~ U
XXVII.
Assuming Toxicity Rating of HCFC-lZ3 is u Good u or Battor Thn I h t of m c - 1 1
Drug (nicrocrystdlfru Surporufon)
Assuming Toxicity Rating o f HCFC-123 fa Adequate, But Significantly Worse Thrn T b t o f CFC-11
0.5
0.5
Exclpieat(s) (As Sorbitm Fhtorr) 1.0 XCFC-123 13.5 CFC-113 HCFC-14lb H F C - 1 3 k Propellrat 75.0-05 .O HCFC-124 Propellat lO.O-nOru
TABLE 10.
1.0 4.5
9.0 75.0-05.0
10.0-none
CAKXKATED OZONE DEPLETION FROM EIDID ITEM (poupsD EQUIVALENCE OF CFC-11)
Yur
Present Formlor (No dungor)
1988
4.000 (HM lbs)
1993
5.000 (HM Lbs)
bxmaLLm U i t h 101 HCFC-124 ( 0 . 0 0 7 ) .
0.028
0.035
"
Without HCFC-124 (0.004)'
0.016
*
0.020
"
0.168 0.156
"
0.210 0.195
"
&mmLxmx U i t h L O 1 IIcrc-12.4 (0.0&2).
Uithouc H a - 1 2 4 ( 0 . 0 3 9 ) .
'Formula's
overall ozone dapletion potential.
=
Suggested Alternative Formulations
TABLE 11.
59
PROPOSED FoIWJIA TRANSITION FOR SOLUBLE HDIDS
1ngedienu
Pcasouc Fornula, I
Proposed Formula. 0
Soluble Dnlg
0.5
0.5
Sorbitan Trloleate
1.0
1.0
Ethrnol CFC-114 CFC-12
8.5
8.5
- Abrolut.
36.0 54.0
HFC-13b
54.0
HCFC-126
36.0
Prarsure (paig at 7Q'F. d r frae) Stracorpherlc 0, D.platlon
s2. 0.88
66. 0.01
F l d i l i t y Concentrate Solution Total Product
Noca:
Fl-10 N o n f l d l e
Ethanol (Absolute) has an Open Cup Flash Point of 65'F handled and filled in explosion-resistant settings.
Flammable Nonf lamnab le
and is readily
60 Alternative Formulations and Packaging to Reduce Use of CFCs
Tho praroztt-day producu of this sub-category a r e t y p i f i e d by the follouing f o n u l r : 83n.
Couuacapti~m ( S p o d c i d . 1 ) Drug TriotbnolPniru KydrCate/Laurrte h r f p h t 151C (Amphocartc or 'Prittorioa' Surfactant) Doiopitad Vicar
10.58 0.58
6.08
77.08 3.28 4.8%
m-114
CFC-12 Prassuro (psig
at
70.F.
air f r e e )
Dmsitp (g/mL a t 70'F) n.ubiiitp
A
47. 1.031 Nonflammable
reasoarbla replacamone formrla is as f o l l o v s :
=I.
Abovo coneeucrrte
92.08
A d i t i o 4 Deionized Uacer A-46 PrqrrU A-.l08
PrOQO1hXlt
16r
4.08 4.08
,
ab8 Isobutane A - 3 1
Ressure ( p r i g a t l O ' F , Density (g/pL a+ 70.F) F l e i l i t y
air-free)
46. 0.983
Transient*
-
*If the foam puff is couched v i t h a l i g h t e d match, a blue flv l l l leap across che surface and immediately go o u t . Tha process can be repeated a t v i l l . Othervise. the product 1s nonflnmrbla because of the 91.08 vacer contenc.
If even thia w r t i g e of f l e i l i t y cannot be coleraced, o r if a more quick-breaking type of foam 1s v m t e d . a t l e a s t 258 of the propellanc must be converted t o HFC-152. (QI,-cHF,), as i n Formula XXXIII:
Suggested Alternative Formulations
Above coneencrate M d i t i o d Doionized Water
-11.
61
92.0% 3.5%
HFC-152. P r o ~ ~ l l pA-60 n~
1.5% 3.0%
33% R o p ~ kA-108 ~ 67% I s o b u w A-31
Resrurm (psi6 at 70'F, DousLty (gfpt at 70'8)
61. 0.987
air-frae)
Fldility
NOQOrut*
-
tho uurl tasC procadurer. Hovever, the propellants (iadtvldually or pra-blendod) a r e flammable and must be dealt v i t h undar highly controlled conditions.
*By
Tho FDA ( D a g D i v i s i o n ) hu jurisdiction over chis product via their XDA program.
m a y MY require the ua.
of a n o n f l d l e propellant.
from nitrous o x i b (N*O). vhich vould cause a mater-foam valve to delfvar significantly mora drug naar tho end of che can than at tha beginning, ApU+
the only n o n f l d l a , non-CFC.choice would ba corcain blends of HCFC-22 ( a t l e u t 40*) a d HCFC-162b.
Xram .
The fornula is u follows:
Abova concentrate
Additional Deionized Water HCFC-22 HCFC-142b Pressure (prig ac 70'F; Density (g/mL at 70'F) Flaponbilfty NOTE:
air free)
92.0% 1.5% 2.6% 3.9a
66. 1.013 None
The pH value must noc exceed 8.2 at 77'F. or che HCFC-22 Vi11 hydrolyse, reducing the pH, and forming chlorlda ion that may act to corrode the aluminum canistar.
Various possibilities for reformulation a l s o exist for the 'future propallants, such w a blend of HFC-134a/HCFC-l42b or HFC-13&/ HCFC-lZb, hut chera may be 7 eo 10 years away from commercialization. alternative'
62 Alternative Formulations and Packaging to Reduce Use of CFCs
F o d r )&)[I1 are
may be the best alternative, since hydrocarbon p t o p e l l a n c s
highly f l r u b l e and m u t be hurdled d f i l l e d in v e l l - v e n t i l a t e d enclo-
surer containing only explosion-proof e g u i p ~ a tand o u t f i t t e d vith an app r o p r h e a electroprocectip. systam f o r dotaction. dam. and o t h e r automatic
responsu.
Present fomulrtionr of t h i s product u e e s r e n t i r l l y like the following:
nxv.
Ethyl U r c r p u n (m-%-SX) ac-12
2.01 98.OI
IUS product is u r d rarely, buc can ba employed to detect methane and carbon monoxidm g u e r in c o d dams and to a u t o m a t i c a l l y r e l e a s e t h e stench to VM
thore rmrble t o hear the audio-darma.
The r e l e a s e d material must be
nonfldle.
An alternative f o d r , using p r e s e n t l y a v a i l a b l e p r o p e l l a n t s is as follovs:
XmJI.
Ethyl Mercaptan HCFC 22 HCFC-142b
2.21r 39.12%
-
Pressure ( p s i g at 70'F: Density (e/& at 70'F)
58.67%
air f r e e )
Flrmrbilicy:
64.5
1.217 None ( b u t b o r d e r l i n e )
F i l l e r s who do n o t have suitable f a c i l i t i e s f o r handling f l a m a b l e p r o p e l l a n t s wt purchase the HCFC-22flCFC-142b (4O:bO) nonflammable blend.
Present formulations c o n s i s t of the following:
-1.
100.0%
CFC-12
Suggested Alternative Formulations
63
Tbeae 6 rad 12 Av.02. cans a r e used as homo, car, and boat sensory alarm aquipmant to souud a high-fataa8ftp (90-110 dacfbel) horn if the system
&cuts
mowmoat. selected sounds, or other oc~urrences. Since large amouncs
of propallme a r e d t r e d rmd.r c d f t f o n s beyond the mukatar's control,
in coquter rooms. o u r spuLins equfpmsnt, a t e . , it is necessary to use a aopflrruble c m a i t i o o or MI e l e c a f c d t e r ~ t f v adadem. e.g..
dispmuers use UI fntemrl dip to carry the liquified gu through the v d w and into tha expuufon chamber o f the horn, vhere it Uost of
up&
to the gueous state.
ON mL
of CFC-'l2 produces 256 m L of gas at 70'F
chilling o f the chamber and icing of the h a i d i t y in the air may occur, but this haa M effect on the horn properties. N ~ r e h e l e s s .to relfew such icing (but not the chilling), some formulas are and atmoapharfc pressure.
Strong
r d s o d to the folloufng:
=SI.
85.03
15.01
In such vapor in
-0.
CFC-12 E t h r n o l Absolute (or Neehano1 Absolute)
cases. 1 mL of product produces 236 mL of CFC-12 and alcohol
Tbe m i x w e is still n o n f l d l e .
Conversion to Mn-CFC fngedientr can be readily effected using t h e
follovfng composftfon: XXXIX.
60.01 40.01
HCFC-142b HCFC-22
Pressure: Prosaura:
63 psig at 70'F 69 psfg at 7Q'F
(air free) (22'Hg' vacuum crimp)
Sface thfs composition fs just barely nodlamable, there fs no lacicude
for adding (flamable) alcohols for de-icing purposes. lo01 HCFC-22 in heavier cans have already taken place.
Some conversions co
Also, unlika pure CFC-12, a d f s t f l l a t i o n affect vi11 accompany any additions of scronsly c h i l l e d F o r m r l ~XXXIX to an e p e q can. The preferencial
64 Alternative Formulations and Packaging to Reduce Use of CFCs
evaporation of n o n f l d l e HCFC-22 d l 1 cause the residual liquid in the can to bmcoao tochnfcdly flammable and lovor in pressure. Although the flam-
nrbility vi11 bo of d
l conaoquence unless tho HCFC-22 sinks to about 32.04
or so, thoro offecu do constitute a drawback.
Any fillers using
rofrlgeration-filling mthod. vi11 hra to &a1150 to pressure-filling tech-
eh. dr.Viry of
1aiq~08.-
p.rt1.l
VICI~LII
(2Z0Hg' minimum) in the can The density d l l be 159
boform inmoducfng eh. liquid to avoid +his offect.
1ov.r ch.n for CFC-12. but tho g u volum par Pt d l 1 bo higher. far Food--
Tho presont exemption is for non meter-spray and non total-release spray pesticides in cormarcill food-handling areas.
A cypiul fonaulatlou for such a product vould be as follovs: XL.
2.08
13.08 62.58 62.58
roxic-ts h h y a t o ~ rE-1 CTC-11 CFC-12
(AS S . D . E t h r n o l 40-2; 2 0 0 ' )
For the foLloving reasons. most of tho original product volume has been replaced vith vatar-based formulas when using hydrocarbon gases as the propellant:
Tho spray cannot bo ignited vlth a f l a because ~ of the presence o f vater: Food-handlers vera using the CFC-typo sprays for Locker rooms, bathrooms, offices, and ocher areas in the establishment; and Tho factory cost o f a 16
Av.02.
flying insacc killer, using C F C s .
v u $0.62/can higher than the cost of the vater-based. hydrocarbon product. not consfdaring manufacturing losses. vhich vould add $0.03 to $O.OS/cm. This vould increase to about $1.00/can more (ninimua) at vholasale prices.
Suggested Alternative Formulations
65
A typical hydrocarbon product formula is as follows: XLI.
2.0% 1.01 0.44 0.11 0.11 6o.h 30.01
Poricurtr Petroleum Distillates (Food Grade) N o n - i d c Emulsifier (Aa 'bean 80, by IC1 America)
brpholiLu S d u u hnroate (Food G r a d e ) Dofoa.izod Water; USP Bydroutbon Blend BIP-40 (Food Grads) 181 PropA-108 331 1~0-b- A-31 494 n-5~A-17
ReSrtU0: 47 p i g at 70'F (21"Hg' vacuum crimp) Dolivery U t e : 0.62 g/sec at 70'F fnitial Density: 0.9Q4 g / d at 70'F F l d i l i t y : None, by standard tests
-
NOTE:
ff
UI
.ahydtour.
The hydrocarbon blend is extremely flammable, and special M C ~ O ~ Swt: be employed to handle and fill it safely.
M
d
d
h
f o d a t i o n is regarded as "essential,"
the folloving uuuld sufffce:
XUI.
2.08 42.01 56.08
Toxicants HCFC-22 HCFC-142b
Pressure: 69 psig at 70'F Purge) Density:.
(vith 22'Hg'
vacuum crimp and
1.213 g / d at 70'F.
The cost, hovever, may-precludo serious fnterest in this formulation. t Soravs
for Birctaft
The present fumigation sprays for aircraft crbfns are composed of che following:
66 Alternative Formulations and Packaging to Reduce Use of CFCs
XLIII .
1.01 1.0% 49.01 49.01
Pyrethrins/Cfnerinr (201 in Petroleum Distillates) Technical Pfperouyl Butoxid.
-
CFC-11 CFC-12
ocher toxicaut sy,rc.u.
such u 2.01 Sumethrin or 21 Resumchrin, are
to be used W e o f c!ta hi&-cost prd sporadic unavailability of ROQCu via the same formulation as PfetMn/Cinerin M W products. ~
F o d a EL abovm are w e d Ln s o y areas. The most rauoauble altenuclve would bo tho folloving:
m.
2.01 40.01 58.0I
Pressure:
-
68 psig a t 70'F (vi& 22'Wg' y. pura.)
1.270 p/d. F l r u b i l f c g : Nolu bMi-:
-
T o r f c m o (As describod just above) HCFC-22 1,1.1-Trlchlotoechme Inhibited (4). vacuum crimp and
70'F
If the generally acceptable odor of l . t , L . - c r i c h l o r o c t h a n ~ - i n h i b i c e dis too noticeable or dfsrgreeable, the much mora costly Formula XLII could be
substicutad.
Al
discussed in Section 3, Cheso sprays consist entirely
OK
almost
entirely of 9-, 15- and 25-pound refillablm cylinders containing 40 to 60% 'Vapona'
(orgmo-phosphate) insecticide and 60 t o 401 CFC-12. These con-
miners are not classiffed as *aerosolsm by the aerosol industry. Nevertheless. it fs appropriate t o identify an accepcable alternative composicion. such as the following:
Suggested Alternative Formulations
XLV
.
60 t o 65% Vaporrr" Xnsectlcido 3S to 608 HGC-22 Proasure: Dmsity: 19on:
-
67
Tochnicnl ( 9 5 8 min.)
About 75-100 p s l g a t 70'F ( a i r - f r e e refill) About 3 t o 78 l i g h t e r than tho CFC-12 product
HCX-22 is A b e t t e r d i s p r r s a u t than CFC-12. a l l o v i n g the use o f a s o ~ . v h . t h i g h e r l o v d of VPPOM ( 6 5 8 maxima). For such fozmulu. the s t a n d a r d amount of Vapona p e r cy1ind.r CUI ba used, urd the same cowrye p e r r e f i l l vi11 apply.
This formula range is too Ugh i n p r e s s u r e f o r o a e r o s o l * c o n t a i n e r s , but chey cm bo r e d l y replaced (if usod) w i t h c y l i n d e r forms f o r this a p p l i c a -
tion.
These sprays MY be otther nonflamable (CFC-based) o r fl-ble carbon-based) according t o the c o n d i t i o n s of use.
(hydro-
For o x m p l o . e x t e r i o r
touch-up p a i n t could bo f l d l o , t y p i c a l l y using 298 Hydrocarbon Blend A - 7 0 to A-85.
The n o n f l d l e types includo d u s t e r s , l u b r i c a n t s . and wld/mildewcides to be used i n such areas as the c o c k p i t . engine, and r a d i o / r a d a r a r e a .
Othemise. air pockots w i t h i n fnstntMnts and banteen close-packed equipment
could be over-sprayed into che flammable range and such vapors be ignited by a spark source.
This moans that, whenever p o s s i b l e , both the p r o p e l l a n t and the coca1 A l s o , the use of solvents such as 1.1.1-
product should be mnflamable.
crichloroethuu-inhibited would o f t e n be c o n t r a i n d i c a t e d because of unwanted e f f e c t s on the dolicrte e l e c t r i c a l o r e l e c t r o n i c g e a r . A q p l c a l alternative formulation could ba p a t t e r n e d a f t e r Formula XI1 A t y p i c a l formulation f o r a wld/mildevcido would be as follows:
68 Alternative Formulations and Packaging to Reduce Use of CFCs
XLVI
.
-
o-Phenylphenol (Aa Dowicide 1 Dow Chemical) I - l b r p h o l i n i ~SOY. Ethosulfates (C-271 LCI) Wrpholixm Quaternary a n f u m Inhibitor (Q.A.I.-nitrIte) Ddooisod Vator Acid form of Ikrfphat o r Kiranol Amphoteric *Zvittorion* S u r f a c t a n t s to pH 8.0 8.2
0.121 0.381 0.101 0.101 24.301 (Ikgligfblo
-
-
50.001
E 1
2s. 001
IICFC-22
Nom:
-
( A n h p d r o r ~ )AS SD Alcohol 40-2 200'
cor~tontmay have to be reduced slightly, dopondfng on presruro and phase compatibilicy. Prmsnrra should not excood 75 psig at 70'F.
I h a vator
Tho Sot-A-Flash Open Cup flash point should n o t be below about 1OO'F for this formula because of the presenco of water.
If even chis minor
degree of product f l d i l i t y is of concern. a
reforarlrtion to use f u w e a1tomrti-m propellants such as the following will be amcossaxy: XLVIX
.
0.201 0.101 59.701 40.001
BTC-212% (801 A.I. quaternaries) Stepan Chem. Quaternary Ammonium Inhibitor (Q.A.1.-nitrite) HCFC-141b HCFC-124
Pressure: 32 psig at 70'F (22"Hg' About 1.28 g/d. at 70°F Density: Flammability: None NOTE:
U
vacuum-crimp)
The slight f l d i l i t y of HCFC-Wlb is councered by HCFC-124.
mentioned in Section 3, the bulk of these products are insecticides
with the following formulation:
XLVZII .
2.01 69.01 49.01
Toxicants CFC-11 CFC-12
Suggested Alternative Formulations
69
The military's
rstionale for requiring a nonflammable formulation is that choy h.v. DO c o n u o l over vhere these dispensers are used. For example, if a EIP wore used to k i l l a r o u h in the cockpit of a fighcer-jet. a sparking source could start s fire
of
in a very confinod, high-tmchnology environment.
P u e i i S resolution of this problom requires us0 of a nonflammable blend presancly 4 1 a b l o (ideally) € I C E propellants, e . g . :
=I.
2.01 b2.0I 56,OI
For other 'critical to the &scriptions
Toxicrnu m-11 HCFC-142b
area,'
n o n f l d l e military-use formulations, refzr
of the folloving formulas:
Foraisa X L V I X : Fozmulr KII:
t4old/nil&vcide; Lubricme; or
Fornulu XX or XXI:
Duster.
If this product type still survives in CFC-form. and if the amount of concentrate is 5 8 or less ( f l d l e or nonflammable), or 20% or less (nonflaauable), an alternative formulation to yield a nonfl-ble
aerosol spray
product could be the folloving:
XL.
LXC-115 for
2 98
-
-
20%
80a
Concentrate Liquid HCFC-Blend: 58% HCFC-142b *21 HCFC-22
--
of Puff-d Food Products C a r t u r n i t a t i o n s Auulied
lhfs product use of CFC-115 has been discontinued because of a Department of Transportation (DOT) 'Special Exemption" alloving the introduccion o f additional nitro- oxide (N,O) propellant. No rekindling of i n t e r e s t i n
70 Alternative Formulations and Packaging to Reduce Use of CFCs
CFC-11s for this uae is inticipatad. although no nonflammable replacement product i s colvrcially available.
The follovixts paragraphs cover axcludod products (vhere the propellant
is d l or p u t of the 'produce..
Only oua w b t a r is thought to be using CFCs for this product t y p e .
Th. approxiP.ca f o d r is u follovs:
L.
451
551
A
Vicar-based Sealant Cancentrota CFC-81.ad: a 1 m-114 601 CFC-12
d e r of dartha have occutrad during the repair of tires containing
am exploriva mixture of air and hydrocarbon propellants, and insurance firms soutimor refuse to coatinw product Ifability coverage. The above formula has been one result of this. It is mare costly and less effective than the sundard 25 to 30- Hydrocarbon Bland A 4 6 formulas. A n altarnative n o n f l d l e formula vould b e as follows:
u.
6Sa 231 12a
Vicar-based Sealant Concentrate HCFC-142b HCFC-22
Ressure: 56 psig at 70'F (air free) ll.NiqJ: 1.087 at 70'F F11Pubilftp: None--but borderline.
uul.
If a lover pressure is required, formulacions would have co use future alternative HFC-134a in place of the HCFC-22.
Suggested Alternative Formulations 71
Ih. q p i c r l l y 30-3St CFC-12 used in there formulas u a nonflammable blovfry .gbUt C 0 p I I I p . s about 3.1 Oil1100 pound. p e r y e r t O f CFC-12. 'Ihe dtbnutlvm agent wt ba nonfl..P.ble .ad c h d c r l l y c q a t l b l e w i t h t h e f o p . Ih. follortry f o d r t i m ir sugge8t.d:
U I.
66t 2% 17%
158
Polyureehru pre-polymbr d i s p e r s i o n D h t f i y L Ethar (DnE) (Moisture Scavenger) HCFC-142b Ha-22
Prersure: 48 p s i g at 70'F ( a f r f r e e ) F l d f l f t p : Combwtible, because of the c o n c e n t r a t e . The HCFC blend is nonflammable. The HCFC/DNE blend is marginally nonflammable.
The p r o s m e L about the
forarlas.
SP ..
u is e x e r t e d by the CFC-12 in p r e s e n t
The vapor wlrw would be about 268 g r e a t e r .
is d e s i r e d , 148 .iCFC-l42b and 12I HCFC-22 could be used. unvmted noishue
If less vapor volume The DKE t i e s up
In the a e r o s o l can urd prolongs che serrice l i f e of the
product.
The curzent fornula is loot CFC-12, and che product is designed as a simple c h f l l e r f o r e m b r i t t l e n e n t o f the gun, a f t e r vhich t h e f r a n g i b l e mass can be cracked a p a r t and removed.
No s o l v e n t s can be used, o r t h e c h i l l i n g
vi11 be mitigated and s o f t e n i n g of the gun surface may result. The proposed a l t e r n a t i v e f o r n u l a is aa follows: LJII.
U.01
54.0%
HCFC-22 HCFC 142b
-
Pressure: 70 p s i g at 70'F (22"Hg' V . C . p l u s purge) Denslty: 1.24 g/mL a t 70'F (CFC-12 is 1.34 g/mL 70'F) F l e i l i t y : Nonflamuble
72
Alternative Formulations and Packaging to Reduce Use of CFCs
This product v u developed by Glmreae, Inc. and marketed as "Drain It YU later sold t o khn 6 Fink Products Group (Sterling D m g Co.) a d t b a diacweinrud because of the high p r i c e .nd numerous i n - u s e O p o ~ by i cham.
probloms. A f o r a J a 1-
F o d a No. LIII could be proposed f o r a non-CFC version,
b u t the item is nou d a d , and no markotsrs seem t o be i n t e r e s t e d i n it as a
future product p 0 8 s i b i l i t g .
Tbse are p r e s e n t l y a - 1 2 o r CFC-12/114 blends f o r t o p i c a l a p p l i c a c i o n b e f o r e localizmd incisions are M& f o r removing v a r t s . minor birthmarks, e t c . Following 1s a suiuble, c u r r e n t l y a v a i l a b l e replacement formula:
LIV.
10.01 50. 01 40. 01
Ethanol
- Absolute
(Pure Grain S p i r i t s )
HCFC- 142b HCFC- 22
Pressure: 67 p s i g a t 70'F (22"Hg' vacuum crimp) Density: 1.19 g/mL a t 70'F p r o p a l l a n t blend and nonflammabia Flrpnnbility: Nonfl-ble product by s t a n d a r d tests. (The ethanol has a Set-a-Flash Closed Cup 56'F.)
-
If &sired. the ethanol can be r c w v e d from this formula.
I t is
included as a p r e s s u r e d e p r e s r a a t , c o s t - r e d u c e r , and germicidal solvent. Hedlcally-approved s p e c i a l l y denatured ethanol grades, such as SDA-17, may be used in some c a s e s .
Formula IXL ( d e s c r i b e d above) is suggested:
LV .
60.01
40.01
HCFC-142b HCFC-22
Suggested Alternative Formulations
73
Products Ln cbfr class a r e uaed t o blow dust off photograph r e c o r d s ,
If hydrocarbons v e r e used, a flammable 9 . 7 g of butanas will cause a11 the a i r i n a 5 5 -
tap. dacks, sey1us t i p s . d so f o r t h .
..(I.,
condition could result;
gallon drum t o b a c o n -le.
Tharefore. dusters should be nonflammable o r
a s s e n t i d l y a o n f l d l e in colposltlon.
Tha Inclusion of s o l v e n t s is con-
traindicated i n ganard.
Formula X X X , discuasad previously, is suggested:
xcux.
6 0 . OI 40.01
HCFC- 142b Ha-22
Ressure: Ressure:
63 psfg a t 70'F 6 9 p s i g a t 70'F
( a i r free) (22"Hg' vacuum crimp)
Uhile these p r o p a l l a n u a r e b e t t e r solvenu than CFC-12, their residence rime
on t a r g e t surfaces d
d probably ba too b r i e f f o r any a&erse
effacc.
When the t a r g e t s u r f a c e is not adversely a f f e c t e d by s o l v e n t s chat a r e more accive than CFC-113, and when s l i g h t l y slower evaporacion races can be t o l e r a t e d , the f o l l o v i n g formula is recoplaendad.
LVI
.
721 288
1.1,l-Trichloroethane HCFC-22
-
I n h i b i t e d (4)
b t f n r t e d u &out ha p s i g ac 7 0 ' ~ (vlth vacuum crlmp) Density: 1.302 g/d. a t 70'F F l d i l i t y : Nonflammable
Pressure:
Uhen extreme p u r i t y and the evaporation r a t e and ocher p r o p e r t i e s i n d i g e n o u t o CFC-113 a r e required. t h e following formula can be used while
74
Alternative Formulations and Packaging to Reduce Use of CFCs
research is conducted about the possibility of replacing the CFC-113 with HCFG-lZ3. or vfth a blend of .bout 50% HCFC-123 and 50% HCFC-141b:
LvfI
.
73% 27%
CFC-113 HCX-22
Thr rupglier of there f u w e altarnative products wuld have eo be c o n u c t d about eh. poaaibiltq o f making th.n available in highly purified fornr.
This i s A ninor use of CFC-113, for which It Is uniquely qualified. The Dow-Cornfng Corporation. a mkar of two such producu, hu examined the possibilities of using l , l , l - t r k h l o r o e t h a m (4) urd methylene chloride and has pronounced thu unsatisfactory. Only two othor poasibilities can be offered: Adhesive Spray: LVIII.
3%
80% 17%
LIX.
3r 4lI
40% L6a
Silicone-based Adhesive HCFC-14lb (Marginally €l≤ HCFC-22 (nn~.) Silicone-based Adhesive HCFC-14lb (MargiMlly fl-ble; HCFC-123 ( N o n f l d h : B.P. HCTC-22 (Nonfl-bla)
-
B.P.
-
B.P.
-
82'F)
90')
90')
NOTES: The Adhesive is marketed as a 50% Active Ingredient disporsion in CFC-113. The supplier should reforsulate the product to use perchloroeehylene. 1.1,Ltrichloroethma inhibited. or HCFC-141b. in order of increasing volatility.
-
The prelininrry results of coxicological tests underway make tho use of HCFC-123 uncertain.
now
Suggested Alternative Formulations
75
There is concern about HCFC-141b becauso of its ur-1 f l d i l i q . Thia is probably suffictencly neutralitad by the 171 HCFC-22 in Formula LVIII t o olimin~ceany fnainaic probhms. Howevar. if a o a f l d i l i t y is an absolute requirement, the dditioa of tha HCFC-123 in Formula LIX provides u t r a cooficlanco, although teating vould be
r.guired. Adhuivm Sal-t
Spray:
NOTES:
Ad
Host of these will vanish
above, for HCFC conponenu.
PI
CFCs become progressively less available,
beginning vith tho 15 t o 258 effoctive raduction in production volume on July
1. 1989. (This effective reduction is due t o the growth in CFC use since 1986, the basaline year for the Kontreal Protocol-required CFC cutbacks.) I n general, CFC-12 can be replaced vith 4%HCFC-22 and 58% HCFC-lL?b for those posribla uses of CFC-12 not coverad in chis section.
Of the 26 product categories examined in t h i s section. most can be raformrlaced t o eliminate or contain much lover concentrations of CFCs. metared-dose inhalant'drug (WID) aerosols are the most difficult.
The
To dace,
ralatively littla effort t o raformulate products seems to have been expended by any of the CFC users, and this is particularly t m e of tha 'future alcernatives,' perhaps because of 'coxicological uncertainties and because the alcernrcives may not becomo comnrcially availabla for sevaral years.
76
Alternative Formulations and Packaging to Reduce Use of CFCs
Pharmaceutical marketers (HDIDs. contraceptive foams, ete.) have exprasaad grm concern &bout &&ling v i t h the FDA Drug Division and reopening
their N M files, especially if rnmeroua f i r m apply for amended NDAs concurrently. thus ovmrlording th. m r l l FDA staff tn t h i s research area.
It ia uehniully passibla to reduce uroaol-rel~tedCFC used to less th.n 2% of th. preaent 2S.S nillion pound volrpw vithin five years vich existlag chrnidr.
Post-1994 reductiaar, hovevar, &prnd
o f the altanutivas and
should br
p.d.
on the toxicology
on what possible rrcrificea in quality a d convenience
to accomodate the rued for maximum CFC reductions.
5. Procedures for and Costs of Substituting Alternative Formulations for CFC Aerosols
I n Section 4. c u r r e n t l y available siubstiCutas f o r CFC a e r o s o l s and chose
chat may be available i n the future were considered f o r a t o t a l of 26 c a t e g o r i e s o f a e r o s o l products chat c u r r e n t l y use CFC p r o p e l l a n t s i n vhole
pare.
Sixty-ona f o r n u l a t i o m were described.
OK
in
For several products, more chan
one f o d o t r a n s i t i o n pa& w a s shown. b u t i n each instance a p r e f e r r e d nonCFC formula w a s rec-ndad. Uhen s u b s t i t u t i n g a l t e r n a t i v e a e r o s o l formulas f o r CFC-based a e r o s o l products. one of tho w s t importaat c o n s i d e r a t l o n s is flaudnability.
Depending
on circunrtancea. one o r more of t h r e e main formulation r o u t e s w i l l be taken. as shown in Figure 1. For firms producing CFC a e r o s o l s . the t r a n s i t i o n t o non-CFC formulacions will increase in d i f f i c u l t y and c o s t (and o f t e n decrease i n a c c e p t a b i l i t y ) as che replacement formulas go from TYPE lA t o TYPE 38 (shown i n Figure 1). The c o s t s of CFCs and c u r r e n t a l t e m a c i v e p r o p a l l a n t s shown i n Table 12 have been taken from p r i c e Lists provided p r i m a r i l y by €.I. duPont de Nemours
6 Co. ( I n c . ) , t h e only source f o r a l l of chc g a s - l i q u i d s .
One p r i c e i n c r e a s e ,
e f f e c t i v e on February 14, 1989, ranged from no increase f o r dimechyl e t h e r to
15* increases f o r CFCs.
The HCFC and HFC p r o p e l l a n t s were incermediate i n
p r i c e range. Table 12 also includes e s t i m a t e s of the coscs of these propellancs in 1993 and 1994 and compares cham with che p r e s e n t p r i c i n g schedule. These C o s t s a r e s p e c u l a t i v e and assume a dramatic i n c r e a s e i n the p r i c e of CFCs.
77
78
Alternative Formulations and Packaging to Reduce Use of CFCs
AU tm: &or tlcn: propdlmlr are m a fldl.
or more HFC or HCFC propollmu is f l d l o . but blend i s nonflammable OM
On0 or more hydrocarbon
propollants is used so chat tho propellant is flppp.ble
is nonfl-able
NOTES:
A propollant is hore definod u 'flamable' f l d h composition (or range) in a i r .
is flammabie
if it can produce a
A concentrate is dofined as f l d l e if it e x h i b i t s a Set-A-Flash (Closed Cup) flash point of less than LOO'F.
P l w e 1.
Aorosol Roforarlatlon Options (1989
-
1993)
Procedures for and Costs of Substituting Alternative Formulations
TABLE 12.
ctraaerr AND 1993/1994 PRICES FOR
vmous
AEROSOL P B O P a u N l S
Currant W l b )
ptop.llo9+
a11 CFC-12
0.79 0.89
CFC-113
1.05 1.40
Eatinrtos for 1993/1994 ($/lb)
1.23
3.00 3.40 3.50 4.00 4.0
NA*
NA.
Diputhyl Ether (DHE or Dyml A) HCFC-22 HFC-152a HCFC 142b
0.38 1.05
0.55
HCFC-123 HCFC-124 HFC 1 3 k HCFC-141b
NA NA
NA
4.00 3.70 4.40 3.00
Carbon Dioxide
0.14 0.18
0.19 0.23
CFC-113 Extrams Purity Grades) CFC-114 CFC 115
-
-
-
1.60 2.&0
t u
Hydrocarboar (Aorosol C r h )
2.00 3.40 3.25
On a volume b a s i s (gdlon versua gallon). CFCs will cost about 42 c h s as mch u hydrocarbons. On a vefght b u i s , they w i l l cost abouc 15 c h s as nnrch. Oa a volume b a s i s . the
HK: and HCFC alternatives will cost about
25 rimes as ouch as che hydrocarbons. On a weight b a s i s , they will cost abouc 12 t h s as much.
On a volume basis. the about 38 t h s as much as the they will cost about 16 t h s a r e difficult t o predict mare
HFC and HCFC alternatives will cost hydrocarbons. On a w e i g h t b a s h , as much. Note chat long-term prices accuracelp than within 5 25%.
On a volmn b a s i s , d h c h y l ocher will cost about 3.7 tires as much as the hydrocarbons. On a w e i g h t basis. i t will cost about 2.9 t h s as arch.
7 0 n cylinders only.
79
80 Alternative Formulations and Packaging to Reduce Use of CFCs
COST OF CONVERTING FILLING LINES
of the curtent fillers and mukotors of non-pharmaceutical CFC-type u r o s o l productr a r e me equipped to handle f l d l e propollants. They could produce TXPE 1 products v i t h ua capitalization. and TYPE 2 products vith minor
upitdizrtion. but for TYPE 3 products must vould have to Q one of the follovhg: C o d t wry hamy u p i t r l t u t i o a , tip.. and educational resources to c o a v o s to hydrocarbon formulas and accspt a statistical risk of fire.
and explosions; or
Close dova their frcilitiea and go to a contract filler able to
handle such products.
The cost to cotwort
OM
wdium-speed (80 to 160 cans per minute (cpm)]
u r o s o l line to the filling of TYPE 3 products vi11 vary vith safety commitm n c levols but vi11 range from $hOO,OOO to $1,200,000. A probable average vould ba $900,000. Table 5, vhich appears in Section 3 of this report. lists 3 6 filler and marketers handling N P E 1 products.
While theso firms handle 90% of the nonpharmaceutical CFC business, it is estimated that an additional 30 to GO firms, often terned "garage" operations, are also filling CFC aerosols. Smaller oporators vho electad to fill TYPE 3 products vould be assuming a substantial r i s k .
They would probably cloae down their operations or rely on
a contract fillor for continulng production.
It is estimated chat about 12 of cho larger CFC fillers vould convert one line to filling
rYPE 3 replacement formulas, because chey currently have
no ouch line and prefer t o continue chair in-house manufacturing activicies for all of chair products. Kost of the remaindor vould convert to only N P E S 1 and 2 products or go t o a contract filler.
Procedures for and Costs of Substituting Alternative Formulations
81
Table 13 shovs estimates of the total indwtry costs of in-house filler conarsiona from CFCs to the TYPES 1, 2, and 3 products defined in Figure 1.
Tha installation of a lfna ab10 to hurdle TYPE 3 products vould a150 parmft cha fI1lar/mukatar to fill ochar urosol producu that commonly use
f l d h products uhm nrch in-houa filling businass is out of reach because of tha hazard. fnvolvad. The pbnuc.utical
industry currently hu approximately 20 markecers
chat sall matered-doaa FnhrlntfoD drugs
(HDID) and matarad-dose contracepci're
foam# for human c o n s q t i o n undar FDA exemptions. A t least
NO
U.S. contracc
this group: Armstrong Laboratories, Inc. (West Roxbury, ,XA) and fillers sath. 3 1 Health Care Specidties Division (St. Paul. m ) . Approximately 10 production lines a r e currently engaged in the manufacture of these produccs.
ma
approximately 96 million u d t s of microcrysulline UDIDs suspended
In the propellant chat a r e d a c w e d each y a u could ba converted co a TYPE LA formula (Formulas xlcv and -1, u doscribod in Saction 4) vithout major cost.
Thera or0 formula a r e recornendad. When the UDID is dissolved in anhydrous ethanol (about 11 million uniis
a year), a TYPE 1B formula (see Table 11) is recommended.
Finns handling
producu in that subcategory are already manufacturing this formula, except for propellant sdection: therefore. conversion costs should be minimal. The last pharmaceutical category is the matered-dose contraceptive foam and its non-metered counterpart. 'Ihe most reasonable conversion for chis product is to a TYPE 3A formula, using hydrocarbon propallant blends.
At
least soma of chase products a r e being manufactured in-house by the marketers. They vould have che option of spending about $900,000 per converted line, or
going t o contract fillers already set up eo handle such products.
The above statements do not consider research (redevelopment) costs. regulatory costs (FDA-NDA), or marketing costs--on1y the manufacturing conversion outlays.
82 Alternative Formulations and Packaging to Reduce Use of CFCs
13.
Conversion Hood.
COST m
m s mx P B E S ~IN-HOUSE FILLER
W. o f Fillers
urns
C O ~ I O N S
Costs
(5)
0
0
13
4,000* 000
12
11,000,000 $15,000,000
-on-phumaceuticd finu only.
Procedures for and Costs of Substituting Alternative Formulations 83
HRHODS AND COSTS FOR DEPefl)PWC ALTEBNAlZvE FORMJUTIONS FOR CPC AEROSOLS
Tha most approprfam vay t o dfrcurs the cost-effectfvenerr of alternaciva appr0rch.s
fa
011
product-by-probrct b u f s .
The b u i s f o r the folloving sizo coutaixur. and 2) the information i n
dfrcursion ls 1) use of m -rage
tho 'Product V o l u n of CH: VarsfoxW c a l w of Table 4 in Sectlon 3.
The
ulculrted costs o f intarlm formilacform u e b u e d on an asruaad dramatic
hcreur in tho prica of CFCI.
The per-can c o s t f n c r a u e of converting: 3r Concentrat.
3r Concentrate 57r cre-11
*or
to F o d o V
65r HCFC-123
32r HCFC-22
cre-12
in the average 1.11 l b dirpenrar can only ba calculated i n terms of 1993/199&
propellant prices, because HCFC-123 fs not yat available and a price has not
Usfng p u f q f o r tho concmntrate and price estfmates from Table 12 the follovfng d i f f e r e n t f a 1 can be calculatad:
been establishad.
-
Diff.
1.11 x 1.08 x [(65r x $4.00 + 32t x $2.00)
-
(57% x $3.00 +
*or x $3.*o)]
-
Dfff.
1.20 [$3.24
-
$3.071
-
$0.204 par can.
Notes:
Anrrlysir uznmes that the current can s i r a s can hold an e x t r a 15 v o l u n percenc o f product. since Fornula V has a lovar density than
thm'prmrene C X forpula (Formala I ) .
d1.r *
net Wfght
Otherwise. a l a r g e r can or a
vll1 b. requfrmd. adding to the c o s t per pound.
Tha 1993/1994 prices are obvfously speculatfva.
84
Alternative Formulations and Packaging to Reduce Use of CFCs
The 1.08 f a c t o r t h s Into account an a n t i c i p a t e d 8% propellant 10.8
(during f i l l i n g ) f o r both formulad, which I s
dbOUt.the
Fn-
duatrp warage f o r these products.
B.uur0 i c MY be impractical to v r i t soverrl years f o r the commercfalizrciop of t h m HCFC-Lz3 uaed in Fornula V, it I s appropriace t o look a t the Fpwdiace comorsion opeion. e.g.,:
Cllculace t b per-cm c o s t inrraaae of comersfon from: 38 Concentrate
3% Concentrate to
57% C X - 1 1
53% CFC-11
26# HCFC-142b
408 CFC-12
18a H&C-22 TYPE IA
rrPE
u
Using c o s t s e f f e c t i v e on February 14, 1989. and p a r i t y f o r concentrate prfcfng:
The cost of CFC Formula I is:
1.11 x 1.08 [(57r x $0.79) + (408 x $o.ag)l
-
1.20 [$0.650
+ $0.1891
$0.967 f o r the CFCs In a 1.11 l b can. w i t h loss.
The c o s t of CFCfHCFC Formula (not l i s t e d In Section 4 ) is:
1.11 x 1.08 [ ( 5 3 % x $0.79) + (268 x $2.60) + (18% x $1.05)]
-
1.20 ($0.419 + $0.626 + $0.1891
$1.478 f o r the CFC/HCFCs i n a 1.11 l b can, with loss.
The c o s t difference vould then be: Dlff.
-
$1.678
-
$0.967
-
$0.511 p e r 1-11 l b average s i z e can.
Procedures for and Costs of Substituting Alternative Formulations
85
Notes :
Aadysis
MSIIP.~ the
c u r r e n t can sizes
CUI
hold an e x t r a 7 volume
p o t c a n t of product. s i n c e Formula V hu a l o v e r & ~ i t y than the p r e s e n t CFC f o d a (Formula I).
Othervise. a l a r g e r can o r a
d l e r rmt w e i g h t vi11 be required, adding t o the c o s t p e r pound Th. CFC conten+ is LPlwdiately reduced from 97% t o 538; i . e . , a LfP reduction.
Ozone d r p l e t i o n is then reduced by about 4 3 . 6 9 .
Ricer f o r Formula 111 and lV a r e n o t c a l c u l a t e d h e r e because the use of mothylelu c h l o r i d r may be d i f f i c u l t i n l i g h t o f res p o s s i b l e human t o x i c i -
ey,
and because, according t o i n h , t r y sources,
the r e l a t i v e l y low v o l a t i l i t y
of l.l.l-trlchloroeEbm.--inhibtted vi11 l e a d t o an i n f e r i o r product f o r many dpplfCdtfOM.
me c o s t of converting CFC Formula I t o : 5 5 8 CFC/458
HCFC Formula rVa i n 1989 v i l l i n c r e a s e by about $0.511 per
cdll:
lOOI HCFC Formula V in 1993/1994 will i n c r e a s e by about $0.204 per can; and 1008 HCFC (+ c h l o r i n a t e & ) Fornulas I11 o r IV vill change s l i g h t l y i n 1989.
The c o s t of a f a c t o r y conversion from a TYPE LA t o a TYPE 2A product i n 1989 is estimated to be $150,000 p e r moderate speed l i n e . option of going t o a c o n t r a c t f i l l e r is a v a i l a b l e .
Noce t h a t the Several firms now use a
c o n t r a c t f i l l e r , and a converted l i n e could be a l s o w e d for o t h e r products o f
TIPE 2A composieions.
86 Alternative Formulations and Packaging to Reduce Use of CFCs
Formala IX (see Section 4) Vi11 be t&n lb per can.
as the standard. filled to 0.76
Th. 1989 cost of the CFC compononta of this formula is as follows: Cost
-
0.76 x 1.0s ( ( 6 5 8 x $1.40)
+
(30a x $0.89)]
0.821 ($0.91 + $0.2671 $0.966 per cam ( w i t h an 88 d a c w i n g loss o f ptopellancs; the 88 is am mstlmaee of the p r o p e l l a m lost during filling).
In Saction 4. f o d a a are presented for 1,1,l-+richloroechane and meter-spray 0 p t 1 0 ~ . If these a r e niLad o u t . ve a r e l e f t vfth a 1989 conversfon to a CFC/?ICFC formula. folloved in 1993 or 1994 by conversion to a HCFC formula. Zhe proposed 1989 'partial conversion" formulation is ehe folloving: 58 Specialty Lubricant Blend
708 CFC-113 258 HCFC-22 The 1989 c o s t of the'CFC/HCFC components is as follows: Cost
--
-
0.76 x 1.08 [(708 x $l.hO) + (258 x $1.05)] 0.821 [$0.980 + $0.2631 $1.020 per cur (vi& an 8a manufacturing loss of propellanrs).
Procedures for and Costs of Substituting Alternative Formulations
87
Camarsioa fn 1989 from CFC Formula IX to the CFCflCFC formula vi11 cos+: $1.020/~
-
-
$ 0 . 9 6 6 / ~ $0.054/~-
Ib. r.duction in CPC coutmat L. 26.38 and the rmduction in ozone deple-
tiou L. 24.2a. A socod stago of eh. raQlctim proc8ss could occur in 1993 or 1996, Vhm XCFC-Ulb should becam snilable.
So.
Soction 4, Formula XII:
58 Spocinlty Lubrlcont Blend
72- HGFC-Wlb
238 nmc-22 U s i n g 1993/1994 prlces, the cost becolus the following: Coat
-
-
0.76 x 1.08 ((728 x $3.00) + (238 x $2.00)] 0.821 ($2.16
+
$0.461
$2.15/cm ( w i t h an 8% manufacturing loss of propellants).
Tho standard CM: (Formula IX) composition must be recalculated for 1993 and 1994 prices. f r o m Table
Cost
-
--
12. to determine m y differential.
0.76 x 1.08 [ ( 6 5 8 x $4.00) + (308 x $2.00)] 0.821 [$2.60 + $0.601 $2.63/cm ( w i t h an 88 manufacturing loss of propellants)
Conversion in 1993 or 1994 f r o m CFC (Formula IX) to HCFC (Formula XII) will
m:
88
Alternative Formulations and Packaging to Reduce Use of CFCs
The 1993/1994 pricing s w w e for CTCs and HCFCs is very speculative. Coat iacra~aoaor ravings in conversion ropresant differentials and could be d j o c t to considarable error.
'Ih. cost of commrting f r a CFC P o d . TX to: ehr 73.78 CFC/26.38 H C X Fornul. OII
1989 price.)
of a
Vi11 rorult in an increase (based
t S O . O ~ ~ / C A X I ;.nd
tho 1008 HCFC Foruula X I 1
will rosult in a &crease
(based on
1993/1994 prices) of about SO.Ul/can. Th. 1.l,l-trichlorootha~and motor-spray formulas are not considered hore becuuo they MY b v e very 1iPit.d
applications.
However, they are the
l e u t costly by far. Tho coat of a factor], commrsion from TYPE IA to a TZPE 1A (HCFC)
formula i n 1989 w u l d be negligible. and Tablet- M
The optimum M d i a t e conversion possibility is for:
Sa Conceneato 70a CFC-113 (Specially purified) 258 CFC-12
58 Concentrate
eo
658 CFC-113 (Specially purified)
108 HCFC-142b 20% HCFC-22
TYPE lB
rYPE 2B
Procedures for and Costs of Substituting Alternative Formulations
The average can size is 0.86 lb net vefght.
89
Costs are calculated as
follovs: F
PO&
O
~ XII: A
XFJ:
Coat
Coat
-
--
0.86 x 1.08 [(70% x $1.40) + (25% x $0.89)] 0.929 [$0.980
+ $0.2231
$1*118/Can. 0.86 x.1.08 [(651 x $1.40) + (101 x $2.40) + (201 x $2.00) 0.929 [$0.910
+
$0.240
+
$0.4001
$1.44O/can.
The differential then becomes about $0.322/can. Reduction in CFCs would bo 328, and ozone depletion w u l d bo reduced by approximately 318.
The same
can s i z e could probably be used for equal w e i g h t s of the alternative formula, since there is ouly about a 3% reduction in product voluw.
The manufaccuring
conversion cost would be n e g l i g i b l e . The preferred 1993/1994 alternative w u l d be Formula XVI (see Section 4):
5.01 Concentrate 55.01 HCFC-141b 30.01 HCFC-124
10.0% HCFC-22 TYPE 2B
Costs are compared w i t h Fornula XI11 (using 1993/1994 prices) as follovs:
Fornula XIII:
Cost
--
0.86 x 1.08 [701 x $4.00 + 25% x $3.401 0.929 [ $ 2 . 8 0 + $0.851 $3.39/cm.
90 Alternative Formulations and Packaging to Reduce Use of CFCs
Formala XVI:
Cost
--
0.86 x 1.08 [ 5 5 * x $3.00 101 x
x $3.70 +
0.929 [$1.65 + $0.201 $2.75/cra.
Tha p r i c e docraue In go-
to
the HCFG formla &en becomes $O.SO/can.
T h i s could b. fuxdmr decreuad if a e h u g e vera M&
purification of
+ 30*
$2.001
for extraordinary
HCFC-14lb volatile liquid component. The sa& size can The manufacturing
could probably ba used. uith the s p p . f o d a w e i g h t .
c u n w r s i m cost should be nagllgible in golng from TYPE lB t o TYPE 28. The comwrsiou of CFC Formula XI11 to:
the 68.4* CFC/31.6* HCFC Formula XIV will result in an increase (bued 0111 1909 prices) of about $0.322 per average-size can for c h t ~product; and the 1001 HCFC F o d a XPI vi11 result in a decrease (based on 1993/1994 prices) of about $0.64 per average-size can for this product. This decrease could dvindle. however, if the HCFC-1Llb requires special purification. Contingency f o d u . such u Fornula X P , are discussed in Section 4 bur a r e not priced here.
The comersion from a TYPE lB to a TYPE 28 formulation should not have a significant impact in the manufacturing area.
Procedures for and Costs of Substituting Alternative Formulations
91
Tho s M d u d foornrlrtion is tho following:
Tho standard
CIP
s i z e is 0 . 5 1 l b .
Ib. c o s t is cllculatad as follovs: Cart
---
0.51 x 1.08 [(7S% x $1.40) + (2Sr x $ 0 . 8 9 ) ] + $0.2231
0.551 ($1.05
$0.7Ol/c.p.
Tho o n l y LPordirtely availabla conversion is
to
tho following formu-
lation:
70% CFC-113 16% HCFC-142b 14r HCFC-22
and to closely related analogs. if a nuinup amount of CFC-113 and CFC-1’2 i s to bo replaced.
92 Alternative Formulations and Packaging to Reduce Use of CFCs
T h m cost is calculatmd as follows:
Cost
-
-
+ 16% x + $0.147}
0.51 x 1.08 (70% x $1.40 0.551 ($0.98
+
$0.384
$2.60 + 14% x $1.051
so.a33/-.
nu prmsonc diffmrmncill th.n bmcous about $0.132/can. T h m reduction in CFCI vould bo 30%. Th. product doruity M u l d &crease by about 110, possfbly rmqufrizxg a l u g o r can for t h m s a w fill wmight, or else a reduction In fill wmight.
T h m d a c t u r l n g couvmrsion cost would be negligible.
T h m ultlmate convmrsion. to an entirely CFC-free formula, could take place around 1993 or 1994 *an
available.
othmrs
are
u s m prop-
t h m 'future alternatives" becomm commercially
T h m preferred fornulation is Formula XI1 (see Section 4). although glwn, accordlug to t h m availability of HCFC-123 and the desire to 01
Folloving is a comparison of the
a cost-cutzing option.
1993/199& pricmr of F o d u XVII
pad
XXI.
(1993/199G l
-
758 CFC-113
60% HCFC lGlb
25% CFC-12
30% HCFC-124
10% HCFC-22 As bmfore. the 1993/1994 cost is calculated as follovs:
cote
--
0 . 5 1 x 1.08 (758 x
s*.oo
+ 2s) x $3.401
0.551 [$3.00 + $ 0 . 6 5 ] $Z.lZ/can.
For Formula IOCI the cost is calculated as follows: Cost
-
0.51 x 1.08 ( 6 0 8 x $3.00 + 308 x $3.70 + 10% x $2.001 0.551 ISl.80 + $1.11 + $0.20]
s1.714
Procedures for and Costs of Substituting Alternative Formulations
'the d i f f e r e n t i a l then becomes $O.hl/can.
L O W , and the reduction in
OZOIU
93
The reduction i n CFCs vould
d e p l e t i o n would bo about 9 6 a .
be
The formula
&OUX 10 t o 158 l o v e r in &Mity +b.n the CFC c o u n t e r p a r t , thus slighcly larger can, or s l i g h t l y reduced-might f o d a / p a c k a g e m y be needed. Because the produce fs being convatted from a TYPE IA t o another TYPE IA
would bo
p r o d u c t - - u s u d n g a throe-c~apoaentblond is p r e p u e d by the s u p p l i e r and
addad t o tha CIP by th. f f l l e r - - , thera uould be a n e g l i g i b l e a f f e c t on
nmufrcwFng comrrion coscs. f l d l e HCFC-141b (B.P.
-
I t is M C rrcollundod that the s l i g h t l y
90'F) be handled aa a s e p a r a t e c o n c e n t r a t e .
of d i r t i l h C i o n effects in storage tanks. the f i l l i n g o f Formula XXI should be as follous:
hC8Us.
From
a three-component blend
in
a bulk tank that
is never allowed
t o sink belou 35 voluma p e r c e n t full; o r From a bulk tank of a cm-component blend of HCFC-l(*lb/124 i n a ventilated. explosion-proof gas-house. followed by s e p a r a t e gassing
of HCFC-22 i n t o the cam. The second o p t i o n would f o r c e a conversion from W
E lA t o TYPE
3A,
which could c o s t up t o about $&Oo,OOO t o $1,200,000 p e r moderate-speed Line.
This is not recornended unless the f i l l e r already has such a TYPE 3 faci1ic:r
in place.
The 1989 p r i c e of converting Formula XVlI t o i n t e r i m Formula X I X vi11 r e s u l t i n an average increase of $0.132/can (CFC c o n t e n t v i 1 1 decrease by 30a). The u l t l m a t e 1993/1994 p r i c a of converting to Formula XXI w i l l r e s u l t i n a decrease
of about $O.bl p e r can (CFC content will then be z e r o ) .
94
Alternative Formulations and Packaging to Reduce Use of CFCs
Formulations v q , but th. - s l a n d U d w formulation for &e popular
microcryrealline suspand.d (drug) solid. eypo is u follovr:
nOID 2 1 Drug rad Excipient Concantrata
24r CPC-11 241 CPC-114 501 CFC-l2
The averago paclnge size is 0.033 lb.
Cor+
-
0.033 x 1.08 [24* x $ 0 . 7 9 + 241 x $1.23 + 501 x $ 0 . 8 9 ] 0.0356 [$O.l90 + $0.295 + $0.4451 $0.0331/caaister
h discussed in considarable &tail
i n Section 4 , the industry has
firmly rejected a11 currently available aon-CFC propellants; therefore, ;here is no fiaMdirtely available alternative whose price can be compared v i t h that above.
The b e s t f u w e dteraativa formula for chase products may be Formula 101 HCFC-124 propellant), which is as follows:
ID(v (the modification vi&
Formula X X v 21 Drug and Excipient Concentrate*
13a HCFC-123** 758 HTC-13h
101 HCFC-124
Procedures for and Costs of Substituting Alternative Formulations
95
W g e d from 1.51 for a better comparison vlth Formula WID. Ab-. *uod
op
this slurrying agent having a sufficiently
Lou t m i c i t y for eh. application. (Oeh.mise, use Foorrulr XXlKI. which hu 4.51 CFC-113, but is similar
kr
cost).
Th. 1993/1994 prica for the
CFC tngredienu of the CFC Formula UDID i s
calculated ma follovs: Cost
'pha
--
0.033 x 1.08 [ 2 4 t . x $3.00 + 241 x $4.00 + 501 x $ 3 . 4 0 1 0.0356 [$0.72
+
$0.96 + $1.701
$O.lZO/canister
1993/1994 coat of th. HCFC a d HTC ingradients in Formula XXV future
replacammnt is calculated aa follovs: Cost
--
0.033 x 1.08 [131 x $4.00 + 751 x $4.40 + 10% x $3.701 0.0356 [$0.52 + $3.30 + $0.371 $0.149/canistar
The cost increase for che HCFC replacement is then $0.029 per caniscer. For manufacturing purposes, Formula XXV is a TYPE U composicion.
The
HCFC replacement fornula is also a TYPE U, and all chrac HCFCs are nonflam-
mable.
Thus. manufacturing conversion costs should be minimal. However. for chese products, the cost of research, increased coxicology
studies. dealing'vich the FDA (NDA-amendment), and IddftiOMl qualiry concrol
methods development vould be considerable.
They are estimated to be $2,500,000per product, for each of the approximately 21 products now an the
U.S. market. Uhen chis is r a d t o the manufacturing, markecing, and other coats. the Lnduscry coca1 for converting is estimated to be about $60,000,000,
96 Alternative Formulations and Packaging to Reduce Use of CFCs
unless a more p r a c t i c a l cooperative approach is used t o q u a l i f y f a m i l i e s o f
similar products.
No M a t e o r short-tern couvarsion appears likely, e s p e c i a l l y in view
of t h m lengw product dralopmut. toxicological t e s t i n g . and r e g u l a t o r y approval t h f r a m o .
The 1993/1994 conversion v i 1 2 .dd a $0.029 cost increment t o che CFC I t w i l l allow a 1008 reductioa in CFC c o n t e n t and a 995 r e d u c t i o n i n OLOM d e p l e t i o n potential. formulas.
About $60,000,000 i n conversion c o s t s is a n t i c i p a t e d , i n d u s t r y vide
Tha dissolved-drug forma of MDIDa have not been d i s c u s s e d (except b r i e f l y i n S e c t i o n 3 ) , b u t their costs a r e c o q r r a b l e t o those of t h e m i c r o -
crystalliru suspeusion fonaa. They r e p r e s e n t less than 108 of t h e business volume and a r e provided by only two marketers, one of vhom a l r e a d y has a m i c r o c r y s t a l l i n e suspension product i n the l i n e .
An additional $3,900,000
conversion c o s t is estimated f o r these tvo marketers.
The total MDID conversion c o s t is t h e r e f o r e estimated t o be about $b4,000,000.
The c u r r e n t produces average 0.16 l b n e t w e i g h t and c o n t a i n about 3 . 2 4
CFC-lU and 4.88 CFC-12. A reasonable conversion would be t o che hydrocarbon p r o p e l l a n t form, using 4.008 Blend A - 4 6 , and 4.001 added v a t e r . NO
NDA t b e .
r a p i d conversion is f o r e s e e n because of the usual 3- t o S-year
FDA
Price comparisons based on 1993/1994 c o s t s a r e t h e r e f o r e r e q u i r e d .
Procedures for and Costs of Substituting Alternative Formulations
97
Cost of CFC Fornula XCU: Cost
--
0.16 x 1.35 (1Oss) x 13.28 x $4.00 + 4.88 x $ 3 . 4 0 1 0.216 ($0.128
+ $0.154]
$0.061/cm
Cast of th. Hydrocrrbaa A 4 6 Blond formula (Formula -1): Cast
*
--
0.16 x 1.25 (loss) x [4.01 x $0.23 + 4.OI x $ 0 . 0 0 5 * ] 0.200 ($0.0092 + $ 0 . 0 0 0 2 ] QO.O019/can
Cost of &ionized water: U . S . P
zh. c o m r r i o n from a CFC to a hydrocarbon p r o p e l l a n t vould save
$O.O59/cUr i n 1993/1994 p r i c e s . This option, v i t h tho a t t e n d a n t c o s t s a v i n g s , will appeal t o those m a r k c a r s vho have thdr
OM
1ind.s)
alraady able t o s a f e l y fill hydrocarbon
p r o p e l l a n t s , o r vho have thdr product f i l l e d by c o n t r a c t f i l l e r s .
Others
will hava to spend from $400,000 to $1.2QQ,QQO p e r moderate speed l i n e , depending on t h e r e l a c i v e degree of s a f a c y d e s i r e d o r a f f o r d a b l e . For those m u k e t a r s vtro wish to conclnue f i l l i n g no&-ble
propel-
l a n t s , o r who a r a required by t h e FOA (Drug Division) t o do so. the immediac's a l t e r n a t i v e is the f o l l o v i n g : Fornula X X X I V Concentrate
92.08
Addad DX-Uater
1.58
HCFC- 142b
3.98
-
2.68
HCFC 22
98
Alternative Formulations and Packaging to Reduce Use of CFCs
zh.
COS+
of this fornula ( m i n u s the concentrata) is as follows:
Cost
--
(1.51 x $O.OOS + 3.91 x $3.25 0.16 x 1.30 (10s.) 2.61 x $2.001 0.208 [SO.OOol + $0.1268 + $O.OS20] $0.0372/un
+
Ib. diffar.n+fd. fn 1993/1991 pricas, b e w a n CFC Formula =I Formula
x1[w
is $0.024/c.p.
Foorarla
and HCFC
is loss expenaiva.
Bacauae of tho FDA (NDA) raqufratnnt, no a d i a t e or short-term conversions a r a practical.
Uarlutarr will probably submit both hydrocarbon and HCFC
f o d u . ami ch. FDA w i l l &cf& which fa safest for tha user.
A coap.rrion from CFC to hydrocarbon A 4 6 vi11 save about $0.059/can in 1993/199& pricas. A conversion of Crc to XCFC vi11 save about $0.024/can in 1993/1994 pricas
.
Corn-rrion to hydrocubon A - 6 6 vi11 allov a
content and a 1 O O I raduction in ozone &plation
loot reduction in CFC
from chis producr.
Similarly.
a conversion to HCFC w i l l constituta a 100% reduction in CFC content and a 97%
reduction in ozone &plation expected from the product.
Tho standard fornula can be huediacaly svitched to an HCFC one, as follows:
Procedures for and Costs of Substituting Alternative Formulations
99
2.01 Ethyl norcaptan*
2.01 E t h y l l f o r c o p w
98.08 GPC-U
to
39.21 HCTC-22 5a.a1 H C F C - I ~
TYPE 28
TIPtla
f r a 2.211. C b S.U
Wf&lh+
fod..
i..
Of
The 2.218 v u daoigned to a l l o v
.thy1 MrC8p-
pOr d
t
MIUP. O f
Thus. the amount of st8oching r&ent p e r s t a n d a r d size can would s t a y constant. The dung0 makes no rsrl coat d i f f e r e n c e , y e t a l l o w both p r o p e l l m t r to be c r l c u l a t o d a t tho 98% the S.P.
sit. can.
lOv.1.
The c o s t dlfferencm can be doveloped aa follows: Dlff.
0
-
0.95 x 1.08 t(39.21 x $1.05
1.026 [$.4116 + $1.4112 $0.975/cm.
-
+ 58.88 x $2.40)
-
(988 x $0.890]
$.8722]
Thua. the replacement formula, vhich t o t a l l y e l i m i n a t e s t h e CFC content. costs about $0.975/can more in 1989. Ozone d e p l e t i o n from this source is reduced by about 97t. F l l l e r s must handle the HCFCs as a pre-blend or install very c o s t l y
facilities f o r handling HCFC-142b as a flamable gas.
The standard formula can be compared vith che imedirtely available alternative, as follovs:
100
Alternative Formulations and Packaging to Reduce Use of CFCs
608 HCFC-142b
100% CFC-I2 eo
40% HCFC-22
TYPE1 Thr cost differoneid Diff.
--
TYPE 2 up
be prosraced u follova:
0.47 x 1.08 ( ( 6 0 % x $2.40 + 40a x $ 1 . 0 5 ) 0.5076 [$1.M+ $0.42 $0.891
-
-
(1008
X
$0.89)1
* $0.492/cm.
Thus, thr HCFC replacemme unit c o s u about $0.492/can more in 1989 and OZOM doplecion from t h i s source is
t o u l l y elininaces the CFC content. reduced by 978.
Fillers must handle the HCFCs as a n o n f l m b l e pra-blend, o r else fasCall very costly facilities for handling fl-ble
HCFC-142b.
Insect Soravr for F o o d - H a Areas The CFC-based product has been replaced vich a hydrocarbon-propelled counterpart.
Formulas can be compared as follows:
158 Concentrace B
158 Concentrate A 42.58 CFC-11
to
42.58 CFC-12 TYPE 1B Nota:
55* Deionized Uacer
308 Hydrocarbon Blend BIP
TYPE 3A
The cost of Concentrate A 1s very close to chat of Concentrate B. They are considered che same.
Procedures for and Costs of Substituting Alternative Formulations
101
The coat differential can be presented as follows: Diff.
DFff.
-
--
Therefor..
0 . 7 6 x 1.08 ((42.5% x $ 0 . 7 9 + 42.5 x $ 0 . 8 9 )
3or x ~o.iao] 0 . 8 2 1 ($0.336 + $0.378 I
-
$0.003
-
-
(55%
X
$O.OOS +
$0.0541
$0.539/ern the a h t a r d
d save $0.539/can in factory cost by con-
verting to the hydrocarbon version.
Ttu CFC vould be eliminated and ozone
reduction vould be 0% of the CFC p a c k g e . A
very costly HCFC alternrta. Formula =I,
v u described in Section Ir
but vduld probably mvmr ba used.
Tha compositions of the current CFC-based product and of a proposed
H a - b a s e d alternative a r e as follows:
2% Toxicant Blend 49% CFC-11 49% CFC-12
2r Toxicant Blend and
S8r 1.1.1-Trichloroethane-Inhibited (A) 40% HCFC-22
The cost dtffarential can be presented as follows:
102
Alternative Formulations and Packaging to Reduce Use of CFCs
Thus, cho n u k e t a r would save $.lOO/can by changing to the HCFC-based f o e . CFC rurgo vould bo olfninrtod and tho ozona doplation would be roducod by &a+97a.
A far wro costly a l t e m r t l a using HCFC-22JIICTC-142b could be used if elm l , l , l - ~ c h l o r o w o r~o w e all-d
for
IOU
rouon.
This product probably doer noc exist in standard aarosol forms. For the lb-, and 2S lb-(not) cylindors MY in us., CFC-12 could be replaced by HCFC-22 vichout f a u of mar-prasaurizrtion. 9 lb-, 15
Cansi&ring
th.t 40a HCFC vi11 do cha disprrsant work of 508 CFC-12, a
c o s t copparisan C U I bo
p.d.
aa folloua:
Cost o f 0.40 lb of HCFC-22 is 1.0s x $1.05 x 0 . 4 0 Cart o f 0.50 lb of C F C - 1 2 . i ~1.05 x $0.89 x 0 . 5 0 Differential:
-
$0.441
$0.467
$0.026
This moans that cho cost of propellant gas per pound of insecticide is only $0.026 mora f o r tho altorrutivo HCFC-22 formula. Anothor approach is to consider the propellant cost in cerms of each
pound of Vapona disparsod.
In this case, tho cost of the HCFC-22 is l e s s ,
since $0.735 of HCFC-22 sprays one pound of Vapona; vhereu, $1.168 of CFC-12 is required eo perform cho samo taak.
A number of different produces fall into this (presently CFC) c a t e g o r y . Tho lubricants, dusters, and insact sprays have already been rsvieved above.
Procedures for and Costs o f Substituting Alternative Formulations
In Forarla =VI,
103
2% HCTC-22 replaces 2Oa CFC-12 in a hydro-alcoholic
system for the control of mold and m i l d o w .
dlriaf.c+me/&odor.ne
For a Le
Av.02. maraga can the c o s t increase for the alternative formula calculaces
a5
follwr: Diff.
--
0.89 x 1.08 (2% 0.9S9 [$0.2625
X
$1.05
- $0.1781
- 20r
X
$0.891
$0.081/~m
A nrch higher-priced. errencially anhydrous HCFC-14lb/HCFC-l24 formulatloa is Formula XLVII. buc its officacp vould probably vary w i t h the available huddfty in ch. afr rod, g a m t d l y . Formula XLVI would be more effective.
Ib. folloving analysis of F o d r XLIII versus Formula XPN applies to nflitaxy flying Laroct sprays, u do the analyses of Lubricants, dusters. ecc.
-
Tho lugast military purchues are for &e LO-Av.02. 28 toxicant, 9 8 %
CFc-12/11 inaecticidos.
These can ba compared w i t h HCFC versions as follows:
28 Toxicants
498 CFC-11 498 CFC-12
28 Toxicants
to
428 HCFC-22
568 HCFC-142b
TYPE lA
TIPE 2A
Tho 1989 cost differencial can bo dotomined as follows:
Diff.
-
0.64 x 1.08 ((498 x $ 0 . 7 9 + 498 x $0.89)
568 x $2.40)]
-
(428 x $1.05 +
104
Alternative Formulations and Packaging to Reduce Use of CFCs
-
0
0.691 [$0.387 + $0.436
-
$0.441
-
$2.341
-$0.662/~=
Thus. a eonrnrsioa t o F o d a X U 1 would cost $0.662 more par averageecm at tho factory c o s t 1-1. F O ~ XLII A c o n u h no CFCs and its ozotu daplatioa patantid wuld ba 38 that o f Foorarla XLVIII. shm
Ibis nuht ruppliar.
110
longar u d s u , according eo DuPoat. tha role CFC-115
No f u w a revivd is anticipated.
EXCLUDED PRODUCTS
Tha prevalant formila types can bm compared as follows:
05% Waeer-based Sealant
22% CFC-110
45% Uater-based Sealant to
338 CFC-12
30a Additional Water 258 Hydrocarbons A-46
TYPE LA
TYPE 3A
45% Water-bared Sealant
20% Additional Water
23% HCFC-lG2b 12% HCFC-22
TYPE 2.4
105
Procedures for and Costs of Substituting Alternative Formulations
Cost drveloprmnu are aa follows:
Forrula L:
Coat Coat
cast
FornrLa =(a):
-
-
0.93 x 1.08 (22% x $1.23 + 33% x $0.891
1.004 [$0.271 + $ 0 . 2 0 5 ] $0.478/cur (for CFCa)
Cost
Cost Coat
Formula LI:
Cost Coat Coat
--
--
0.93 x 1.08 [30% x $0.005 + 25% x $0.181
1.004 [$0.0015 + $0.0650] $0.047/cm (for extra water and A-46)
0.93 x 1.08 [20r x $0.005
+
23% x $2.40 +
12I x $1.051
1.004 [$0.001 + $0.552 + $0.1261 $0.682/cm (for extra vacar and HCFCs)
Dfffarentfals then becoma ar follows: Formula L to =(a):
Foxmula L
Co
a decreaae of $0.431 p e r can (factory cost)
LI: an lncreaae of $0.206 per can (factory cost)
A l m o s t no substantive fnformatfon on this product has been found.
I t is
an exoclc abrasive spray used for high-technology applicacions. Approximately 250.000 units a year are used.
ElLPfnacion of the present 32% CFC-12 formulacion is suggested in favor of a 32% HCFC-l42b/22 (17:15) bland.
106
Alternative Formulations and Packaging to Reduce Use of CFCs
Coat comparison is aa followa:
--
-
1.01 x 1.08 ((328 x $0.89) (17# x $2.40 + l S 8 x $1.05)] 1.09 [$0.285 SO.408 $0.158] -$0.306/clrr (factory c o s t ) differentid This will 0lirLrutm CFCa frror this aourcm ad reduce ozone drpletion by Cost
-
-
-
t h l a product by 978.
Th. suggoaeed trParieion is from a 008 CF- 2 f o r m l a t i o n to a blend o ad 568 HCFC-142b (sa. Foreul. LIII).
I HCFC-22
The c o s t compuiron is &a follocn:
Diff.
Diff.
0.59
-
X
1.08 [LO08
0.6372 [$0.89
-
X
$0.89
$0.162
-
-
(I x
$1.301
-
$1.05
+ 568
$O.SBl/can
-
X
$2.&O)]
factory cosr:.
The switch to HCFCs w i l l cost $0.581 more p e r average can a t the f a c c o y ? and eliminate CFC eofrsions from this source.
depletion from these products w i l l r e s u l t .
A 9 7 t reduction in ozone
(Aa of July 1, 1989, DuPont and
Allied S i g n 8 1 w i l l no longer s e l l CFCs for t h i s application.)
This product 1s no longer on the market and w i l l probably nor: be revived.
The present and comparable f u w e HCFC fornulor can be compared as follows :
Procedures for and Costs of Substituting Alternative Formulations
101 Ethanol
eo
107
- Anhydrous
SO* HCFC-142b
4or HCFC-22
TYPE LE F o d a IV(r):
F o d a IV:
Cost
Cost
-
--
---
TYPE 21 0.39 x 1.08 [SO* x $1.40 + &Or x $0.891 0.4212 [ $ 0 . 7 0 + $0.3561 $O.WIS/cm (for tho CFCs)
-
factory cost
0.39 x 1.08 [SO* x $2.40 + 408 x $1.051
0.4212 ($1.20 + $0.421 $ 0 . 6 8 2 3 / c m (for the HCFCs)
-
factory cost
'Tho differoncirl in prico is $0.237/cm.
A
transition t o tho HCFC formula would elfminate CFCs in chis product OZOM dopletion from ahis source by 97r.
and reduce
A
transition from 1008 CFC-12 to a blend of 60r HCFC-142b and CrO% HCFC-
22 is suggested. as follovs: The cost differential should be as follows:
0.43 x 1.08 [ ( 6 0 8 x $2.40 + 408 x $1.05)
Diff.
Diff. Diff.
-
0.4614 [$1.640 + $0.42
$0.450/can
-
-
factory c o s t
$0.8901
-
(1008 x $0.89)]
108
Alternative Formulations and Packaging to Reduce Use of CFCs
Th. f o l l o v i n g t r r a s i t i o n is suggestad:
721 l , l , l - T r i c h l o r o o t h a ~
7s* CFC-1u
2sr GC-12
to
TYPE U
Diff.
0.39 x 1.08 (758 x $1.40 + 25t x $0.89 28r x $1.051
Diff.
0.4212 [$1.050 + $0.223
-
I n h i b i t e d (4)
2aa HCFC-22
TYPE IA
Diff.
-
-
$0.242
-
-
(72% x $0.36 +
$0,2941
$0.310/cpq
This change vould elininate CFCs from this source and l i m i t ozone d e p l e t i o n by these products to about 3% che c u r r e n t level.
No s p e c i a l manufacturing c o s t s vould be incurred.
The HCFC formula
vould be about 3 t o 42 l o v e r i n d e n s i t y , so changes i n can s i z e o r net veighc vould probably not be required.
The c u r r e n t f o d a cannoc be replaced v i t h any combinations of HCFCs Ocher formulations now a v r i h b h . provided.
OK
I n 1993/1994 a replacement formula could be
The two a r e compared, using 1993/1994 p r i c i n g , as follows:
Procedures for and Costs of Substituting Alternative Formulations
109
31 Concentrate
31 Concantrate
72r CFC-113 (Purified) 251 m-l2
411 HCFC-14lb a1 HCFC-123
16* HCFC-22
Presant F o d a :
F o d a LX:
%a
Cost
Cost
--
-
-
0.51 x 1.08 (728 x $4.00 0.551 ($2.880 + $0.8501
+
25% x $3.401
$2.055/can (factory cost) for CFCs
0.51 x 1.08 1418 x $3.00 + 601 x $4.00 + 161 x $2.001 0.552 [$1.23 + $1.60 + $0.321 $1.736/can (factory cost)
differential is thus $0.319/can.
(The HCFC f o r m l a is less costly.)
A tamporup r e f o d a t i o n can be created by replacing che CFC-12 vith
181 HCFC-22.
Ihe calculation is os follows:
Cost
--
-
0.51 x 1.08 (82% x $1.40 + 18% x $1.051 0.551 [$1.148 + $O.l89] $0.7367/~=
The differential then becomes $0.7367/can (CFCflCFC) $O.OS97/can.
-
$0.6770/can (CFC)
110
Alternative Formulations and Packaging to Reduce Use of CFCs
Tho present CFC-12 produce
A c o m e r t i o n to a 601 HCFC-142b
C08CS
a r e u follovs:
+ 4Or HCFC-22 formula
can be suggested. and
eb. COS+ w u l d then be:
The d l f f e r e n t f d bem~eenthe cvo formulaa is thua $0.807/can.
This crtagory includes miscellaneous uses too small to be recognized CFC suppliers and the fnduatxy at large.
by
I t also includes unauthorized o r
i l l e g a l appLicationa of CFC p r o p e l l a n u to various aero801 products.
I t doesn't include CFCs u a p a r t of Halon f i r e extinguisher formulations o r CFC aerosol-sire r e f r l g e r r t i o n / a i r conditioner r e f i l l u n i t s , although these a r e s-eyed
u a p u t of
&e
aerosol product volume per year: and i t
does not include the aerosol-size s t e r i l a n t s , baaed on about LO% ethylene o d d . '+-do
in 90a CFC-12.
These produces have a sales u n i t volume of about 410,000 cans.
fill is estimated t o consist of 0 . 5 0 lb CFC-based ingredients. is handled as if &e products ware medical solvents.
The can
The category
11 1
Procedures for and Costs of Substituting Alternative Formulations
Cost
--
Present CFC cost: -sed
$0.6770/cm
82% CFC-113 and 18% HCFC-22 formula c o s t :
$0.7367/can
$O.O597/cra.
Cost differential:
Table 14 r r r r u l z e s eh. short-tam (1989) d long-term (1993/1994)
prlce differratfrlr of tho CFC-bued products &scribed saction.
in detail in chis
Tho double-dashes ( - - ) In Table 14 signffy that shorz-tern. fully corractim measures
CUI
bo uk.n, and that the longer-tern availability of
future ‘ a l t o m a e l m ’ propellants is of M consequence. Triple dashes signify that there is 110 &finable rhort-tam roformrlation activity. *arm
reuoruble d d e n g e exists that a product has been discontinued,
zeros (0) in the unit wllQovn
(---)
col-
have been used t o signify that there is no
or suspected production of the products.
For the tire inflator, the
cost of only one formula option has been calculated on a yearly basis: OM
w i t h a blended hydrocarbon ( A - 4 6 ) propellant.
the
n e alternative (nonflam-
mable) version is too costly eo consider.
In terms of n m u f a c w i n g chutgeowrs, such as the purchase of new tmiu, new gu-houses, new moniroring equipment, employee education, etc., in-
house fillers vould spend an estinnted total of $15,000,000 for nonpharmaceutical icema. ~ e u t i c r and l medical products are more difficult to revise. requiring more testing. more davelopaenc, linkages with the FDA (NDA), i n addition to Punrfaccuring revisions.
Toea1 costs are estimated to be approxinrtely $ 7 0 , 0 0 0 , 0 0 0 , unevenly divided b e m e e n nuketars who contract-fill and those who self-fill. h n t y - w or onney-chree products are involved i n the lf0I.D area, for .a increment of about $64,000,000. The rest are involved i n che contraceptive foam area. for an increment of about $6,000.000.
112
r. .?
w 4 m
J
-
n
I
Y
-
-
C
m
a
a Y
8
r)
a e a m U
0
a m m a
Y
a e Y
0
2
e
4 Y
u
0 In
OI
9 0
a
i
u
-
w
Y Y
0
0
Y
<
r. 6
e
o
0
. .
o
0
o
0 0
,
o
0 0
? m .
9
0
0
9 0 0 0
I-
f:
i
5 Y
0
U
8.
0
ii
u 0
Y
9
a H
f
d ..
6
Y 0
9
0
I
0
m
rl C
u
e d d
s
4
d
. 0. 0. 0.
0
d
d
a
rq -4
0
I-
a
rq
0
0
s
OI
0
0
9
0
0 0
9
09 c
d
0 0
0 . 0
z s 0
cy
\ w
Y
9
r) U
C
L1
u
Y
r)
6
U
hl
d
m
a m m
s
.
.
0,
=.
o
.
o
A
o
0
9
(L.
Y 0 0
m m
t
W
0
9
0
0 0
9
0 OD m
0
(L.
a
I
Y
4 V
4
U
N 0 d
0
0
0
Alternative Formulations and Packaging to Reduce Use of CFCs
A
v,
A
*
8
E )
6
u c a
r
d
c mw a u A
O Y Y
‘ Y e 0 ‘Y(L.c
Y
a
r)
m
2’ Y
a 0 d I
a m
Y U
U
d
Q Y &
I
I
,
d
.
4
. 0
.
00
o
6
m
4
0,
W
0
9
0
0
00
U ‘y
U
i
I", d
d
d Y
L1
0
d
n
cy
3 0 I 5
k
Y
n 0 l
d
3
u
3 C
d
m
0
a
n
6
4
E
a a 0
PI
Y
a d
0
d
Q
i Y I
a d
d
d
N
Y U
a 4
L1 0
r
d
0 6
d
0
c
Y
4
2
PI
0
4
PI
P
Procedures for and Costs of Substituting Alternative Formulations
I
a
Y Y 0
a
d
c1
YI Q
C
d
113
114
Alternative Formulations and Packaging to Reduce Use of CFCs
pBocmuBEs FOR Q u a r c ~ CFRon CFC
M ALTXNATIVE MRMIJIATIONS
Th. progression o f events f o r changing formulas l u a been covered t o some u t m t u r l i e r in thb a d o t h e r r o c t i o n s , b u t it is more f u l l y d o f i n e d in the
folloving p u a g r r p h r .
Ordor
Mpropollrnu.
prepare and t e a t sampler.
Dovelop a n a l y t i c a l moth&
f o r quality assurance.
Dewlop s p o c f f i c a t i o ~f o r q u a l i t y c o n t r o l . -lop
can/valvm c o m p a t i b i l i t y w i t h product. i n c l u d i n g veighc loss
&a. t . n p e r d t U e sensitivity. r e d u c t i o n s i n active i n g r e d i e n t u a a y , and my other changer.
Provido K a t e r i a l Safety Data Sheets on chemicals. c o n c e n t r a t e , and complata f o d a .
T e s t new p r o d u c t ( s ) in p i l o t f a c i l i t i e s , if a v a i l a b l e . Ordor
MU
a q u i p w n t as necessary.
h s t a l l and p e r f o r n *shake-d~vn*on new equipment. Obtain spore p a r t s , manuals. and educate employees on t h e use o f new equipment.
Iartpll aplosion-resistant. h i g h l y - p r o t e c t e d gas house if d e a l i n g w i t h TYPE 2 or TYPE 3 formulations.
Procedures for and Costs of Substituting Alternative Formulations
Prepare
Mv
cost infornrtloa:
Prepue
0.y
product labels, l i t e r a w e , advertising, and time-
115
tables.
Educate sales perso~molPI t o adv.nr;rges/disadvantages. coscs, ecc. Educate dfstrlbutors. Prepare for o r b r l y transition ia the nrrketpl~ce.
The complexlq of reformulating vi11
VAT
incre.afng wlith pharmaceutical drug types.
vith the producc.
The list of procedurss
is not mait to be c o ~ l e t e ,merely indicative.
For a group of 26 product categorles. the costs of short-term and/or long-tern formula revisions have been calculated for current and opcimum f o d u . and later extendad into the product cost increases or decreases
shoun in Table 14. Data on product size. restrictions, estlmates. etc. have been included. u vel1 as predictions about the reduction of CFC content and the corresponding reduction o f stratospheric ozone depletion by CFC source.
116
Alternative Formulations and Packaging to Reduce Use o f CFCs
Complete eliPinrtion of CFCs is considored p o s s i b l e on a s h o r t - t e r m b u i s f o r about 10 of the 26 product c a t e g o r i e s covered.
of ~ n u f a c t u r i ~ r o s e a r c h / q u r l i t cyo n t r o l / r e g u l a t o r y h . 8 POU UP^ t o a t o t a l of about $15,000,000 utftritio8 h&vm b..a prosantad. T for w n wp r o b u d .bout $70,000,000 for d w g products. Elements t h a t could rffect th.80 &err f n c l u b tha folloving: Data on &a
C08t
&hrkoter/fillerr
l
e
e the marlucplace:
& h r k o t o r / f i l l e r s going e n t i r e l y t o c o n t r a c t f i l l e r s : P o s s i b l o cost sabiny from cooporation i n the FDA/NDA process: C o a l i t i o n 8 alloving several ~ r k e t e r st o sell o m FDA-approved
f o d a / p a c k a g e : and 8.duction i n sales volume. so that smaller lines can be used. Considarable formulation work and r e l a t e d a c t i v i t i e s a r e b e i n g conducted a t this time, and the industry f o r e s e e s a 2Sr r e d u c t i o n in t h e a v a i l a b i l i t y o f
CFCs by J u l y
I. 1989,
Montreal Protocol.
cawed by impleaontr+ion of che f i r s t phase of t h e
6. Conclusions Sections 4 and 5 have examined reformulation possibilities for 26 categories of CFC aerosol products that have enjoyed exempted or excluded status relative to the CFC bans and limitations placed on the aerosol industry by the U.S. EPA and FDA in 1978. According to the particulars of their u s e . some of these products may be easily reformulated to exclude CFCs. and some
may be difficult to reformulate. Several cannot be reformulated vith existing alternative propellants. but mast await the commercialization of the four "furure alternative' propellants described in Sections 4 and 5.
Others must
not only w a i t for the development of these new propellants. but must then go through the 3- to 5-year NDA procedure imposed by the FDA.
AEROSOL USES FOR UHICH CFCS ARE DIFFICULT TO ELIMINATE (AND POSSIBLE INTERIM
REFORMULATIONS) The seven categories of aerosol uses from which CFCs are most difficult to eliminate are discussed in this section. However, partial or interim reformulations of some categories to decrease CFC use are also noted.
Table
15 lists the categories and the U.S. consumption of CFCs from these categories in millions of pounds per year.
The perceived need for CFCs in these products
is based on the lack of available alternatives that can completely replace the CFCs at the present time; hovever. approximately 40 percenc of the CFCs now used in exempted or excluded U.S. aerosol products can be immediately
replaced.
Further, alternative non-CFC formulations for the seven remaining
CFC-dependent categories are judged technically feasible, pending the commercial availabilicy of four 'future" HCFCs and HFCs.
117
118
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 15.
AEXOSOL USES FOR WHICH CFCs ARE DIFFICULT TO ELIHINATE
U.S. ConSuPption of CFCS (EM lbs/yr)
CFC k r o a o l Product
Cartrcn Mold Raleuer
1.5
Ltbricmta--for Eleetric/Elecadc AppliCrtiOM
1.9
Lubric.nu--for Pharmaceuticrl P i l l and Tablet Rearea
1.0
S o l w n t cleaners, h a t e r s . e t c . for
6.0
Electronic/Electric Equipmant ,Y.tered-Dore Inhrlane Drugs ( I D I D )
3.9
Contraceptives for Huem Use
0.1
Solvents--Kedicrl
0.6
TOTAL This is (15.0/25.5)
-
5 8 . 8 a of the present u r g e level.
15.0.
119
Conclusions
Kay necassuy a e t r i b u t a s a r e product p u r i t y , s u r f a c a - s p r a y c h a r a c t e r i s t i c s . f a s t avaporaeion
of all b u t
% -ilicy
tha l u b r i c a n t , and nonf'iamnability.
a t a i b u t a r a l a t a s t o s d a q during l a r g a - s c a l e Using a d d i t i o d product (us i l i -
i n t a r r f t t a n e use in uuproeoctad a r a u .
c0p.s) p n n o t a s surf=.-coating
c h u a c t a r i s t i c s buc addr mora l u b r i c a n t than
medad, causing voiding problams i n tha moldad piacas.
Tha uaa o f v o l a t i l e
solvena promotas surfaca-coating characteristics. b u t if they a r e flammable tha t o t a l product vi11 becoao n d l e .
Tha mnfl&la
s o l v e n t s are
r a s t r i c c a d t o aothylana chlorida and. p o s s i b l y . 1 . 1 . 1 - t r i c h l o r o e t h m e ( 4 ) .
Tha l a t t a r is not quit. b o l a t i l a anough f o r most uaes, and t r a c e s contaminate moldad p l a s t i c s and elastomars b e e a w e of its solvency. e f f a c t i v a b u t is a p o r s i b l a mutagen. so-
Kathylene c h l o r i d e is
This solvant can remain d i s s o l v e d
to
& p e a i n tha & p o s i t e d s i l i c o n a film. and may than c r a z e o r matte che
d a c e
of molded p a r t s .
I t is an exmemaly scrong solvent.
See formulations
111 and IV in Saction 4. Tha idea o f w i n g a mater-spray valve has been discussed w i t h one mold r e l e a s e marlcater: hovever, employees o p e r a t i n g molding machines tend to g r o s s l y overuse thase mora c o s t l y p t O $ w t s .
Also. meter-spray valves do not
work w e l l with s t r o n g s o l v e n t s . Ona reformulation approach
is t o r e v i s e t h e formula to a combination
CFCflCFC c n e , rhus reducing the CFC usage. 58 Silfcona
NOT:
608 CFC-L1 358 CFC-12
For example. by using: 5 9 Sflicona
Ern :
38 I s o p r r C (Heptanes)
229 HCFC-22 708 CFC-11
CFC c o n s u q t i o n could be d a c r e u e d 26r ( o r 0.39 HH l b s p e r y e a r ) .
120
Alternative Formulations and Packaging to Reduce Use of CFCs
CFC-11 will be a necessary i n g r e d i e n t of mold r e l e a s e r s until i t can be r e p l a c e d vith a sultable n o n f l d l e , vexy v o l a t i l e l i q u i d such as HCFC-123:
B.P.
-
02'P.
Thm production of wldod p l u t i c o r e l a s t o m e r i c p a r t s a f f e c t s many indrt.trlu. and cettlkrly th. electric and electronics indwtry. A nuchine, f o r exa@e. MY p r o b e p u t s f o r *sep.itip.* i n b t r y OM day and a *~enritip.* one th. n u t . Providing d i f f e r e n t l u b r i c a n t s f o r each of the M
vould be hard o r fmposrible. E l e c t r i c and e l e c t r o n i c p a r t s must be
perfectly mldad a d cprry e s s e n t i a l l y no embedded o r I m p r e p a c e d i m p u r i i i e s .
Key necessary a t t r i b u t e s arm p u r i r y , surface-spray c h a r a c t e r i s t i c s .
in+rinaic n o n f l d i l i r y aad reasonably fast evaporation o f a l l b u t t h e lubricant.
CFC-113 is a p r e f e r r e d c a r r y l n g agent.
U n l i k e other chlorinated
s o l v e n t s . such as r&8thylene c h l o r i d e urd 1 . 1 . 1 - ~ i c h l o r o e t h a n e ( b ) , i t is not r e a d i l y pyrolfzod t o form c o r r o s i v e agents that could change r e s i s t a n c e s and o t h e m i s e harm d e l i c a t e equipment. H e t e r - s q u i r t a p p l f c a t i o m m i g h t allow the f n c l u s l o n of a h i g h e r p e r c e n u g e (to 70\) of l u b r i c a n t p e r a e r o s o l can. vhich may be a v i a b l e s o l u t i o n ( w i t h HCFC-22 p r o p e l l a n t ) f o r those a p p l i c a t i o n s t h a t can be handled by means
of an e x t e n s i o n cube that f i t s i n t o the a e r o s o l valve button. t o be conducted in this area.
Research needs
See t h e d i s c u s s i o n of Formulas X I and X i n
Section 0. As s h o w bmlov, t o reduce CFC c o m q t i o n t h e CFC-12 can be replaced v i t h an a p p r o p r i a t e amount of HCFC-22:
Sa S p e c i a l t y Lubricant
S \ Spacialey Lubricant 65\ CFC-113
352 CFC-12
TO:
73\ CFC-113
22% HCFC-22
Conclusions
121
This vi11 reduce the CFC c o n t e n t by 238 and consumption by 0 . 4 4 t9H lbs per y e a . I t MY be possible t o restrict the CFC product t o electrdslic u s e s , and use
nom-CTC sprays f o r ordinary e l e c t r i c motors, crude r e l a y s , and ocher items
chat do n o t require
A
high degree of p u r i t y .
ih. Ultimate elldzmtiom of CFC-113 from l u b r i c a a u r e q u i r i n g i t depends 09
pnd
the future avdlabflity of liquid HCFCa. such u HCFC-123 (nonflammable)
HCX-14lb (slightly f l h l e ) .
The Latter vould have t o be used wich a
d f i c i e n c amnmt o f HCFC-22 t o eIfPirute amy ia+riruic flammabilfcy of chs complete product.
Another p o s s i b l e interim fornulation is 58 Lubricant, 558 CFC-113, and
408 HCFC-142b. If this f o r n u l a t e s t s o u t successfully. the CFC COnCent would ba reduced by b2.18. or 0.80
m
lbs/yr.
This product is sinflar t o the previous o m . I t normally c o n s i s t s of 708 CFC-113 and 158 CFC-12. (See Formula X I 1 1 in S e c t i o n b.) Key a t a i b u t e s a r e h i g h - p u r i t y , nonflammability and surface-coacing a c t i o n ; everpthing b u t the l u b r i c a n t evaporates quickly from t h e d i e s . A
short-cam, partial cornartion can be
M&
using che f o l l o v i n g
formula:
Formula XN ( s e e Section
I)
5% Concentrate (FDA Approved)
65% CFC-113
LO1 HCFC-142b 20% H a - 2 2 This change would e f f e c t a 32% reduction i n CFC c o n t e n t , f o r a reduction in CFCs used of 0.32 m l b s p e r year.
122
Alternative Formulations and Packaging to Reduce Use of CFCs
Complete conversion, which will require the use of future alternative fiCFC-123 ( ~ d d l e and/or ) HCFC-14lb (slightly f l d l e ) , is several y e u s avay.
100 pruontly rvdlable oonflrPlble solnnta can begin to compare vith CFC-W for thi. application. Tho use of ochers w u l d cauae d i e contamination aad Lacluston of utranoous maemrials Ln the tablets and pills. efficiency transfer o f lubricant to the press dies d
The high-
d be Impaired as vell.
Electroulc circuftry chillers and related products should also be
includad in this extremdy large category, which accounts for 23% of all CFC aerosol materials. Again. CFC-113, vhila d q u e f a its selective solvent action on greases and oils, does not h u m plastic or elastouarlc components of circuit boards
a d ocher sensitive equtpmnt.
It also has the appropriate levels of volatil
i t y and purity, and it is n o n f l d l e . Instead of the usual formulatfon. 73% CFC-113 and 25% CFC-12 (Formula X V I X . Sectfon 4). a short-term partial conversion eo Formula X I X could be Mda :
70% CFC-113 168 HCFC-142b 1G8 HCFC-22
In this case, the CFC reduction is 30a. for a decrease In CFCs consumed of 1.8 MU lbs pet year. The final conversion w f l l have eo await the availability of HCFC-123 or
of HCFC-14lb. For strategic planning purposes, tests should be undertaken w i t h samples of there HCFCs t o see if they can replace CFC-113.
123
Conclusions
The c h i l l e r sub-category uses s t r a i g h t CFC-12, p o s s i b l y amounting co 2 0 4 blend. of th. CFCs usod in the mdn category. The u t i l i t y o f the nonfl-ble should ha t a r t a d t o discover any problems, such as the HCFC-22/142b ( 6 0 : 6 0 ) ,
minor f l d i l f t y of a surface from vhich much of the HCFC-22 (nonflammable) h u 0~apor8ted. 100 o h r option8 u e c u r r e n t l y availabla. A f u t u r e o p t i o n b. 20r ECFC-124 d 80% HFc-130r.
This indu8txy can & no p r o q e r a touard reformulation with t h e Studies vith l a b o r a t o r y samples
p r e s e n t l y availrble a l t e r n a t i v e p r o p e l l a n t s .
of the p o t e n t i a l mv p r o p a l l m t s should be encouraged, assuming t h e toxicolog-
ical tests now being conducted u l t i n r t e l y permit the marketing of these propellants. k soon a8 tha toxicoloey t e a m a r e r u c c e s s f u l ~ ycompleted. the i n d u s t r y
the FDA and begin tha NM proceaa, which will take 3 t o 5 years t o corplete. OM problw is that several f i b haw N D h that a r e 20 years old. and they M longer h a w a technical staff a b l e t o develop a new product t h ~ would t meet a11 the r e q u i r e m n t s of a t o v i s e d NDA.
can approach
This is year.
a l a r g e i n d u s t r y , producing 107 m i l l i o n units
of i n h a l a n t s a
l h t k o t e r r claim their product saves thousmds of lives a year and makes
o t h a r lives more bearable.
If the industry works now on future a l t e r n a t i v e s , instead o f waiting u n t i l 1993 vhen the t o x i c o l o g i c a l t e s t s w i l l probably be
complatad, che length o f tima needed f o r Completing the NDA amendment process and going to markat vith a
MV
product c a n be s i g n i f i c a n t l y shortened.
The
use of discontinued FC-C318 ( W o n t ) should also be considered.
R e f o r m l a t i o n vith hydrocarbon a l t e r n a t i v e s could be completed very
quickly if permitted by the FDA. a t which p o i n t the FDA NDA amendment process could comence.
124
Alternative Formulations and Packaging to Reduce Use of CFCs
It fr difficult to m e s s the 'essentiality"
of foam insert contracep-
It MY be a highly discretionary alternative to oral contracaptives or other methods. or it MY be a physical or emotional necestives (sparmicider).
sity
AS
vioved by s o y uaers.
In .PJ went, the grun+ity of CFCs
cons-d
in thir product category is
vmry lov--belov 0.1 EOI a s p e t year.
These produces are generally for gauge bandage adhesives and adhesive rewvers.
The primary silicone-adhesive supplier (Dow-Corning) has stated
is acceptable. The They may not have conaidered the f u w r CFC alterna-
that, for technical reasona. no solvent besidas CFC-113
reuon(s) is rmhrovn. tives.
It may be th.t a complete converrion vi11 haw to avait the commer-
cialization o f HCFC-l6lb (vi*
a similar solvoncy profile).
In the .shot= term, since prejent formulas a r e propelled vith either
253
CFC-12 or 5% CO, gas. it may be practical to gain a partial conversion by using 18I HCTC-22 u the propellant.
A further reduction fn CFC consumption
may ba made by using 110 CFC-162b vith 161 HCPC-22.
In the latter case, formulas vith 90 to 95% CFCr will be replaced vich one containing 70% CFC-113. This vi11 reduce the CFC content by abouc
(22.5/92.5)
-
26%, decreasing the quantity of CFCr required for this product
POT&NTIAL FOR E D U G n O U OF CFC USE IN EXEMPTED AND MCLIIDED AEROSOLS
The CFC usage data presented in Table 15 can now be augmented to include
CFC reductions that can be certain products.
in the short term by partially reformulating
Table 16 shows possible reductions projected in CPC
consumptfon fn the U.S.
scenarios:
M&
These reductiona are based on the following
Conclusions 125
PBOJECXED ANNUAL CFC CONSUUFTION IN THE U. S , UNDEB DIFFERENT S C R W U O S (nX US/YR)
TABLE 16.
1990 Vsaga Scenario
herat CFC Producta
C
~
t
i
O
P
1990 Usaga Scarurio
O M
Iva
1995 Usage Scenario Thrae
2000 Usage Scenario Four
Hold R.1eu.s
1.50
1.50
1.11
0.00
0.00
Lubricantr-E@
1.90
1.90
1.10
0.00
0.00
Lubricants-
1.00
1.00
0.68
0.00
0.00
Solvents-E/E
6.00
6.00
4.20
0.00
0.00
HDDID Inhalants
3.90
4.00
4.00
5.25
0.50
Contrrcepeives
0.10
0.10
0.10
0.00
0 .oo
0.60
0.60
0.46
0.00
0.00
-
10.so
-
0.00
-
0.00
0.00
0.00
25.50
15.11
11.65
5.25
0.50
Tabla-
-
Solvents Kedicrl ALL O
m
126 Alternative Formulations and Packaging to Reduce Use of CFCs
%muLans: Ru w e of CFC-11. CFC-12. CFC-113, CFC-114, and CFC-115 would no longer
br pemfttmd for urosol products currently exempted or excluded from p r 6 w ragulatiom ruuicting their w m . w i t h the following exceptfona : Roleue agents for molds used in tho production of plastic and elastommric matsriols; tion-coruumor articles used as cleaner-rolvencs. lubricants, or coatings for electrical or elec+ronic equipment, including frmermu : Lubricpllrs for r o w ublet press-punch machines;
.
Solvents for medical purposes: and
Metered-dose inhalant drugs, contraceptive vaginal foam and o t h e r human drugs as authorized by the FDA.
fn addition t o the i t e r listed above, the use of longer be pemitted. and limited to 75a by weight
in Scenario One, for the first four products CFC-11, CFC-12, CFC-114, and CFC-115 will no the amount of CFC-113 Ln such produccs vi11 be of the total formulation.
chis scenario, and the 'furure alternative propellants' must be capable of replacing CFC-113 and CFC11. Also, the FDA m u t approve hydrocarbon use Ln contraceptives.
A l l the above item are included in
Conclusions
127
F W l y , in this scenriio a11 the above itapply, as vel1 as the folhring: 1) there must aoc b8 my cmuwl delays fn FDA's NDA Anadmoat process. md 2) tho respective fndusczies must proceed with tho nacesurJr rasurch vtthout delay. T d L i 17 compares eh. reductions in CFCJ called for by the Montreal Protocol VFth the reductions shovn in Table 16.
s?uR-m CFC REDucnous
me nonflnnuble blend of HCFC-22/142b (40:60) hu a pressure of about 63 psfg at 70'F. air free. and thus compares w i t h CFC-12, which has a pressure of 70.69 psig at 70'F. air free. Since the blend is M C quite as high in pressure, yet hu an average molecular weight (and thus dispersive volume) very close to that of CFC-12. ft m y be M C O S S ~ to ~ ~ increase the volume by 5 to 105 above the amuut of CFC-12 when replacing ft. This is illustrated by the folloving reformulation:
gCFC/CFC Fonnuls
3% Concentrate 57% CFC-11 40% CFC-12
3% Concentrate 56% CFC-11
28% HCFC-142b 1 5 5 HCFC-22
This s h o w how conveniently the CFC-12 can be replaced w i t h an existing
propellant blend.
Formulation chemists have additional latitude they can explore to develop certain advancages; e . g . , see the follovlng formulas:
128
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 17.
COKPAKISON OF noNTREu PROTOCOL AND QUICKEST REASOHMU CFC REDUCTION
Monumal Protocol
2S.5 ~JRIlbr
Scenarios 1-4 (see Iable 16)
25.5 l4l4 lbs
20.4.
15.0 or 11.7'
16.3. 5.25
10.2' 0.0
tha levels of GFCs co-d in 1986 by the U.S. aerosol industry. A c d reducdona vould conridat t o e d U.S. CFC consumption f o r a l l
%asad on
applicatioru .
P o achieve a reduction
i n CFCs t o 15 . O MU lbs. the CFCs in a l l nonessential with HCFC, HFC, o r hydrocarbon a l t e r n a t i v e s .
aerosols m u t be rep1ac.d
To achieve a reduction t o 1 1 . 7 l4l4 l b s , i n addition to the above s u b s t i t u cfons, as mzch HGFC o r other p r o p e l l m u would have eo be added to non-drug, 'essential' products u possible. replacing a l l ehe CFC-12 content and perhaps minor amounts o f CFC-113 or ocher CFCs. (This would be d i f f i c u l c zo accomplish in l e s s than 1 to 1-1/2 years.) The cos+ of a11 reformulatad products would increase. i n many cases quite d r a s t i c a l l y , as rho= in Section 5 .
Conclusions 129
38 Concentrace
38 Concentrat. 608
608 CFC-11
‘3%-11
21a HCFC-142b 168 HCFC-22
57t HCFc-142b
Coqued w i t h the HCFC/CFC
Compared vith the HCFC/CFC
f o d r . increases coae, lightena
f o d a . reduces cost.
&
~
increases density slightly,
i miniafrer ~ , CFC-11.
and increases CFC-L1. Extending the rationale behind Formula B vould result in t h e following
fornula:
38 Concentrate
758 CFC-11 228 HCFC-22
Less coscly
38 Concentrat.
91a CFC-11 68
CO,
Still less costly
3% Concentrate
aaa cFc-ii 9 % Propane A - 1 0 8
costly
Tba reduction of CFCs vould not be as significant in these formulacions. A
final approach, vhich may noc be practical for every application,
would use CFC-113 in place of the CFC-11. as s h o w below:
3a Concentrate 358 CFC-113 (Purified)
62% HCFC-142b
130 Alternative Formulations and Packaging to Reduce Use of CFCs
lh reasons f o r using this approach aro as f o l l o v s :
A heavy, s u r f i c o - c o & t i n g spray can bo ard. w i n g less CFC-113 than
CFC-11; ad CfC-lU i . roportod t o ba approxlmatoly 00* u damaging t o the
rtrato.gh.ric o t ~ l t layor . u CPC-11.
Tho CFC-113 1s d f i c i o n t t o qual1 uxy minor f l a m a h i l i t y of t h e CFC142b during product uao, piking i t n o d l . p . b l e . Also, compared v i t h t h e CFC Formula, the CFC c o n t e n t is reducod by ( 6 2 / 9 7 )
-
648. and the ozone d e p l e t i o n
p o t e n t i a l is reduced by:
This is, howvet, an unusually c o s t l y f o r n u l a . about $1.22/lb o f CFCfiCFC highor ttua tho CFC formula.
This axmrciso shovs chat CFC-12 can be replaced v i t h t h e nonflammable blend of HCFC-22/142b ( 4 0 : 6 0 ) o r vith
SOM
o t h e r blend of these a l t e r n a t i v e
p r o p e l l a n t s , depending on concentrace and use f a c t o r s . t o roplaco
tho CFC-11 vith 10-208 l e s s CFC-113 and gain
protection. tho
I t is a l s o d e s i r a b l e the added ozone
Tho drug a e r o s o l s ( i n h a l a n t s and c o n t r a c e p t i v e s ) a r e overseen by
FDA (NDA) and cannot bo reformulated i n this fashion. Studies that should be conducted before f u r t h o r r e s t r i c t i o n s on CFC
a e r o s o l s a r e announced includo tho following:
1.
Offering formrlation/pacluging advice t o a f f e c t e d marketers and smoking their feedback on product p e r f o r o r n c e , manufacture. and standards compliance. a.
For exanple:
W i l l a propoaed product sound a boac horn loudly enough. long
enough. and vfthouc i c i n g up o r o t h e r complications?
Conclusions
b.
Can
a
proposed product be d i r a c t l y gassed v i c h HCFC-22 i n
1 f L l l a r s ( g a s s e r s ) without b l o v - b y , e s s e n t i a l l y ~ 1 prassura v a p o r - l o c k , guht b t e r i o r s t i o n a f f e c t s , e t c . ?
c.
Oil1 the f o d a t i o r u be coruidmrad s a t i s f a c t o r y v h i l e l i m i t e d by eh. h p u m e n t of T r a n s p o r t a t i o n (DOT) t o p r e s s u r e s of 180 psig a t 130'R
d.
If CFC-113. h e l d fn
OM bulk tank, and HCFC-22. h e l d i n an0th.r b u l k t;mL, are pra-blandad a t the f i l l i n g p l a n c , then placad in a d l (1.000 U.S. Gallon) run cank designed t o supply the blend t o tha p r a r r u r m - f i l l e r ( g a s s e r ) - - a l l o w i n g the g u s a r t o f i l l the CIP in a ona-stag. o p e r a t i o n f o r CFC-
113/HCFC-22 f o d u - - u a any problems causad by d i s t i l l a c i o n
Ln the (VUiablY f i l l a d ) CAU md
Cank. w i t h
a i r remaining i n t h e
c o n t r i b u t i n g t o p r a s s u r e , ere.?
Nota:
Thts f i l l i n g option, which favors t h e l a r g e r f i l l e r , conaartms CFC-113. compared w i t h w i n g 750-lb dnuna of t h a t s o l v e n t . The bulk price is also -re a t t r a c t i v e than the drum
p r i c e , though this fr o f f s e t t o s o w degree by a l a r g e r frrvantory.
2.
Examining the r v e f l a b i l i t y of HCFC-142b (CH,-CClF,) pocencial f o r ftrr greatly increased use.
in l i g h c o f the
C u r r e n t l y , t h e sole U.S.
manufacturer is Penmalt Corporation. which uses a complex,
souwhat antiquated synthesis dut is r e f l e c t e d in the p r e s e n t $2.&O/lb price. tha p u t a t
Allied-Signal Corporation has made t h i s producc in
chair Baton Rouge. LA f a c i l i t y . b u t t h e i r equipment
w t stLl1 be i n placo.
may
W o n t f e e l s HCFC-142b is a major s o l u t i o n
to &a CFC problem. has developed a much-improved manufaccuring
process. and promises t o supply HCFC-142b a c a l o v e r c o s t .
131
132
Alternative Formulations and Packaging to Reduce Use of CFCs
LONGER-RANGE CFC REDUCTIONS Longer-range CFC reductions vi11 probably bo associated with eliminating tho us0 of CFC-113, as in the folloving: Elimination of CFCs ( P I CFC-113) from tho still-permitted 'ess.n+ial-ure:
rum-mdical products: and
Elimination of CFCs from motered-dose inhalant sprays, hair restorers. and contraceptive foam products which are under FDA control and the subject of NDAs. Subject to laboratory confirmarions and field testing, one or tvo of the 'future alternative" propellants, namoly HCFC-14lb and HCFC-123. might be used to replace CFC-113.
Because of tho slight flammability of HCFC-14lb. it mav
be necessary to blend it r i c h nonflammable HCFC-123.
123 required to produce nonfl-bility
Tho proportion of HCFC-
is nor known.
Used on 1988 production figures, and coaforming with the suggested r u l e
earlierin this section, a projection of about 7.55 million pounds of CFC-113 a year must be considered.
(Nora:
This is the ozone depletion equivalenr: of
about 40.25 million pounds of 1.1.1-trichloroethane
-
inhibited. of which
about 6.000 million pounds are said to be made annually. ) Replacement formulations have been suggesred earlier in Section 4: in particular. Formulas XXV and XXVII for the microcrystalline suspension type metered-dose inhalant drugs.
Little or no work tovard commercializing these
options has yet been done by the pharmaceutical industry--either in the U.S. or worldvide.
They require three propellants nor nov in commercial produc-
tion, although each is available from industry pilot plant production. Industry spokesmen suggesc they % have formulations available in t w o to three years, after which they could go to the FDA to begin the 3- to 5-year
By chis cimo. the propellants w i l l be commercially available. In sucmrory, they are visualizing a commercialization dare of 1996-1999.
NDA process.
Conclusions 133
One of the m o "best fornula" options. F o r m u l a XXVII. requires L . S t CFC113 u p u t of the rlurryfng agent for n o n f l d i l i t y . This vould amount co a use-Level of about 0.176 million p o d per year. based on present U.S. production volumes P o d r 1
. could be a reserm option:
ff the toxicological resulcs
oberinrd for !ICFC-L23 preclud. this propellrPt from bring uaed in
sprays, the a1terrutive F
o
d
d
d have to be considered.
inhalant
The ocher
option would be to force the pharmaceutical induatry to somehow cope vich che challenge of slurrying and grinding their drug/excipiont Items with a Liquid, f l a a d a l e propellant before filling aerosol curistars w i t h the mixture. The industry states that they do not possess this technology, although che possibility of cryogenic rlutrping exists.
The other lwdicrl products, solution-type inhalants. the virucidal Inhalant for bronchopumonla victims, contraceptive foam. and hafr rescorer, makm up approximately 10-12r of the CFCs used for medical purposes, or some 0 . G million pounds a year.
This industry should be amenable to the commer-
cialization date of 1996-1999 mentioned earlier for the microcrystalline suspension inhalant sprays.
Several possible intrrlm alternative formulations for the seven caregorfes of CFC aerosols still considered 'essential" have been discussed in datafl.
Elements of the proposed CFC reduction plan have also bean discussed
and compared Vith the Kontreal Protocol for the years 1989-2000. Furrher recommended studies on aerosol formulations are also discussed. A longer-tern CFC reduction plan would first involve eliminating CFC-113 for a11 non-medical aerosol products (assuming 'future
alternatives" are
useful) and vould effect a reduction of 84.3Q--frOm 25.5 million pounds a year of CFCs used to 4.0 million pounds a year.
This could occur by 1993 or 199G. The final phore would consist of eliminating CFCs from the "essencial-
u r od s o l products by becwecn 1996 and 1999. me- ~ d l ~
References 63
E
11301: March 17, 1978.
United Nation8 w r o a P . n t Progr-, tht hploto ttu OZOM
Ir.
1.1.1-trichloroothane (mothy1 chloroform) is a l s o an ozone-depleting nrbstanco. although it is ~t
5.
6.
Montreal Protocol on Substances
Lyor. Ffarl A c t . 1987.
Dum. D. P.
rubjoct to the Montreal Protocol.
“CFC Propellants Today,“ Part 1, Aerosol Age. J u l y 1988
The information in the 'Notes. to Table 3 was provided by John J . Daly. Jr. of DuPonc. February 1989.
7.
C o d c a t i o n with Trevor Lloyd, Mckughlin-Gormloy-King Co., February 1989.
8.
Co-ication
9.
This vas the conclusion reached by the Scientific Working Group at the
with Carl Olson, Technical Roductr Corp., February 1989
third session of the ad hoc Working Group of Legal and Technical Experts for the Preparation of a Protocol on CFCs CG the Vienna Convention for the Protection of the Ozone Iayer. Geneva, Switzerland, April 27, 1987 (UNEP/UG.172/CRP.9).
134
Information on MDlDs
Appendix A-Additional
Tha addandum in the follouing pages provides salected information that
MY be of interest coaceraing inter-spray CFC-containing ethical drug aerosol productr
.
METZBED OOSL IEHALZX (OPAL) Boahrlnger-IngelheisPharmaceuticals, Inc. Adrenergic bronchodilator. S u l f a t m . USP in a 15 PL container
0.225 g Ma--proterenol
-
Package provides 300 inhalations of 0.65 mg par dose. Two to three equivalent EO one inhalation. Limit: 12 inhalacions per day.
doses
-
acipient:
Az44maT
Sorbitan Triolaate
UiIlfam H. Rorer, Inc.
(OW)
Corticosteroid--forcontrol of bronchial asthma.
Anti-infl-tory
0 . 0 6 0 g Trinncindone Acetonide in a 20 g canister.
Package provides at l e a s t 260 inhalations of about 200 micrograms (mcg) per dose, of which 100 ncg are delivered from che unic--invitro. (Above 260 inhalations, the amount delivered may be inconsistent.)
Formula: Ucrocrysullina suspension of drug in 1% ethanol, plus CFC12. (Suggest a slurry of 23.08% drug in ethanol is prepared.) Toxicology:
AEROBID
-
Teratogenic to rats and rabbits, causing cleft palace and/or internal hydrocephaly and/or axial skeletal defects a t low incidence. Typical findings for glucocorticoids in animals.
Forest Pharmaceuticals. Inc.
sfizLL( ( O W )
Antl-fnfl;mutory
;“d
anti-allergic corticosteroid--forbronchial
Uthnr.
About 0 . 0 2 1 g Flunisolide in
a 7 g
135
canister.
136
Alternative Formulations and Packaging t o Reduce Use of CFCs
Packago providos 100 fnhalatfons of about 250 mcg drug, of which total systemic availability fs about 40*--at 2.0 mg per day. The 2.0 g/day l f f o l fs Cho chronic adult maximum. F o ~ A :nicrocryrtalliru suspension of Flunisolido hemihydrate, with sorbitan triolorto (disporsurt) and CFC-11. CFC-12, and CPC-
116. ToxlcoLo~~y: T o r a t o g d c to r a u pad rabbits at 40 ocg/lg/day to 200 rgFg/&y, aa a r m othor corticosteroids. ALSO fetotoxic. B
m
G l u o , Inc. (Research Triangle Park, NC)
m ORAL IlwILep ( O m )
A corticostarofd for control of bronchial asthma. Aboue 0.0084 g of BeClOMthMOne DiQropionate, USP in a 16.8 g canister.
Packago provides at l o r s t 200 fnhlations. For adults, the maximum drily i n t h should not excood 20 fnhalations.
Formdr: Microcrystalline suspension of beclomathacone dipropionaretrichlorownofluoromsthano clathrate in oleic acid and CFC-11 p l CFC-12. ~ Toxicology:
BECOXASE IUS&
Teratogenic and embryocidal in the mouse and rabbit ( b u t not tho rat) when applied at ten times the maximum human dose par kg; e.g., cleft palate and absence o f tongue. Claxo, Inc. (Research Triangle Park, YC)
(NASAL)
Identical to Beclovent Oral Inhaler, except for nosepiece. DECADROB PHOSPUTE BLsPIHaLEB (ORAL)
Herck. Sharp h Dohme Division
Adrenocorticosteroid--for treatnent of bronchial asthma. About 0.107 g of Dexamethasone Phosphate in a package provides about 170 inhalations fn a 12.6 g canister. Formula:
Suspension of 0.5 and fluorocarbons.
Toxicology:
-
4-micron prrcicles of drug in 2% ethanol
Appendix A-Additional
DECdDROlD PXOSPEA?E mIN4ZU (NASAL)
Information on MDlDs
137
Herck, Sharp C Dohae Division
-
Idmutical to Deudron Phosphate Respihaler except for nosepiece.
MD-
(ORAL)
U k a r kboratorles, Inc.
Blood a s s d constrictor (crdal)--for trertlunt of nipafnes and prodtoma. About 0.225 g of Ergotamine Tartrate in a 2.5 PL (about 3.45 g) vial.
P.36 mg drug per dore; thus, about 25 inhalations per vial. Formula:
Fine puticle suspension of ergotamine tartrate, vich sorbitan triolaate. CFC-11. CFC-12, and CFC-114. Drug i o abouc 0 . 5 5 4 V D .
Toxicology : ~rBLLpIL-ISO( O W )
Bikar Laboratories. Inc.
Adrenergic bronchodilator--for control of bronchial asthma. About 0.030 g of Isoproterenol Sulfate in a 15 mi. (20.4 g) vial. 0.08 mg of drug per dose, and 300 doses par vial.
Formula: A fine suspension of about 0.158 v/v Isoproterenol Sulfate p o v h r in sorbitan trloleate, CFC-11, CFC-12. and CFC-114. Toxicology:
XEDIIlrCLEB-EPI ( O W )
Riker Laboratories. I n c .
Adrenergic bronchodilator--for temporary relief from bronchial asthma. Epinephrine Bitartrate in a 15 EL (20.4 g) v i a l . Each inhalation delivers 0.3 mg of the drug. Formula:
Epinephrine Bicartrace (ruspcnsion'l) in cetylpyridinium chloride, sorbitan triolaate. CFC-11. CFC-12. and CFC-114.
138
Alternative Formulations and Packaging to Reduce Use of CFCs
DUO-11ED-
Rilur Lboratories, Inc
(ORAL)
kirmargic bronchodilator--for control of bronchial asthma. Isoprotoronol H C l md Ph.nylophrinr Bftartrrto in 15 PL and 22.5 mL
m.
tcfr use ralouos 0.16 mg Isoproteroaal H C l md 0 . 2 4 mg Phenylephrine B i t u t r a t o in .bout 0.0s mL o f lnerts. Tha 15 PL v i r l provides 300 fnhlrtion+. Formla:
Two drugs in nfcronttod particlor suspended in cetylpyridinium chloridr, sorbitaa trioloato, CFC-11, CFC-12. and C F C - 1 U .
Toxicololpr: C e i g y Pharmaceuticals Division
Nurl decong.strm:. Xylowtazoline Hydrochloride, USP.
(Hetor-Spray: OTC.)
0.18 drug, in 15 PL aorosol boctlo--plutic coated.
Formula: Torico logy :
NO-
(ORAL)
Schering Corporation
&ta-adroiurgic bronchodflator--for reversible obstructive airvay disorso, uui for provention of exercise-induced bronchospasm. &ch use discharges 0.090 mg o f Albucarol in about 0.126 g of inerts (.=.a. 0.093 PL minimum). Tho package s i r e is 17.0 g (12.5 m L ) . 'Ihe canistar providor at l e u c 200 doses.
Formula:
O.llr Albuterol, Oleic Acid. CFC-11. and CFC-12.
Toxicology:
Teracogenfc in nice at l&X the maximum human dose.
Appendix A-Additional
A ~~ocorticorteroLd--relief of h e inhdatlon prod&.
S ~ ~ C O O of .
0.042 ng of the drug.
Information on MDlDs
139
rhinitis and inflammations.
Package size is 16.8 g.
(1.4mg of drug is prarent in the cmister. equaling 0 . 0 5 % (200 doaer/un). Foorarlation:
nicrocryrtrllh rurpenaioa of beclowchaaone Dipropiowate trichloroumsfluoromotham clathrate in oleic a i d . CFC-11. ind CFC-12.
Toxicolog:
Teratogenic t o laboratory animals.
(ORAL)
VM-
Schering Corporation
S p l v aa the above, except for use of oral applicator.
mRluIAm (ORAL)
Uinthrop-Breon Laboratories Div. Sterllng Drug, Inc. Mr'd by Sterling Pharmaceuticals, Inc
Beta adrenergic bronchodilator--for bronchial aatbma and bronchospasm. 0.8% Bitolterol Herylate, 38% ethanol. Aacorbic Acid, Saccharin, Henthol. CFC-12. and CFC-114.
Bottle provides at least 300 doses of about 0.050 mL each, containing 0.37 mg of the drug. Teratology:
-LIB
Oral doses eo rats and rabbits up to 557 times the maxinun human inhalation dose, and i n rats to 284 times t h ~ dose. t produce no teratologic effects. (Some clef: palates vera obtained through subcutaneous injection.)
ImALzu (ORAL) Selective Bet+drcnergic
C l u o , Inc. (Research Triangle Park)
Bronchodilator--relief of bronchospasm.
About 0.118% Albuterol in a 17.0 g canister. providing over 200 inhalationa of 90 mcg drug each.
140
Alternative Formulations and Packaging to Reduce Use of CFCs
Fodation:
Drug (mfcronfrmd suspension), i n oleic acid, CFC-11, and a12.
~oxico~ogy: Teratogen. especially vir subcutaneous routes.
-
Data-Adremrgic Broacbodilator--relfaf of bronchospasm.
Eacb 7 . 5 mL (l0.S g) cadstar prowidor about 300 x 0 . 2 5 og inhrlacions. Fodrtioo: T e r h t d f M Sulfate sorbitan ~ri01e.t. a-11 m-114 CFC-12 Toxicology:
NOM.
0.075
0.105 2.580 2.580
5.160
0.714
1.oao 24.571 24.571 49.1U
Appendix A-Additional Information on MDlDs
Boahringor-Ingelhelm hlupant Matered Dose Inhaler Forort Pharmaceutical h r o b i d Inhaler S y r t u Ul1li.n H. Borer, Inc. m o l t Inidat cluo, Inc. hlovmnt Oral Inhdar cluo, Inc. ikconasa NualIoh.ler C.f w PhrrP.cau+fcalr Brachdra ~acuitoam s p h r t o bspfhrlar Karck. sbrrp 6 Do& Dacdron Phosphrto T u r n i ~ i r o Karck. shrrp 6 Dobe Rikor Laboratories, Inc. Duo-hdfhder U k m r Laboratories. Inc. Ka.dih.lar Epi Rikar kborrtorias. Inc. Medihaler Is0 B i h r Laborrtorias. Inc. Medihalar Ergoeamfna Scharing Corporation Frovanti1 Wtnthrop-Broon k b s Tornalate Vpncanua N u l l Inhaler Scharing Corporation Vanceril Inhaler Scharing Corporation Ventolin Inhalor C l u o . Inc.
-
BRANDNM
-
ORAL Bronchodilator ORAL Corticosteroid ORAL Corticosteroid O
W Corticosteroid
NASAL Corticosteroid ORAX. Bronchodilator ORAL Corticosteroid NASAL Corticosteroid
ORAL ORAL ORAL ORAL
Bronchodilator Bronchodilator Bronchodilator
CONSTRICTOR
ORAL Bronchodilator ORAL Bronchodilator NASAL Corticosteroid ORAL Corticosteroid ORAL Bronchodilator
PXODUCT DISTXBUTIONS
m
ERGOT. VE1m
A
Alupant Azmacort hrobid Baclovent Baconua Dacadron K. Rasp. Decadron Ph. T u b . Brechaire Hedihalar - Epi Hedihaler Is0 Hedihaler Ergot. Duo-Hedihaler Provancil ToLnalata Vancenasc Vane aril Vancolin
141
21 20
BRONCHODILATOR
ORM.
xx
7
TAR=. 9 B B L w o R A L CORTICOSTEROID
xx xx
17
xx
17 13
xx
13 11 20 20
xx xx
xx
xx
xx
3.5
20 6 30
xx
17 17 17 17 17
xx
-
-
-
-
16.0
8
5
3
1
xx
xx
xx
xx
Appendix 6-DOT Regulations for Compressed Gases Departmoat of Transportation
Rogulatfotu for Caapross.d C u e s Tfth 49 Cod. O f Foderal b g U h t i O M Part 173
142
Appendix B-DOT Regulations for Compressed Gases
Rosoarch and Spoclal Programs Administration, DOT (d) pofsonow mfstures. A mlxture containing any poisonous material. class A. or Irritating materlal In such proportlOM that the mlxture would be l l polsonous ~ under 4 173.326ta) or 4 173.381(8) must be shlpped In packagings aa authorized for these polsonous materials. (29 FR 18743,Dec. 29.1964. Redeslmnkd at 31 FR 6606. Apr. 5. 1967. and m e n d e d by h d t . 173-70. 38 FR 5309. Feb. 27. 1973. m d t . 173-04.41 FR 16079. Apr. 15. 1976; 45 FR 32697. Mny 19.1980l
-
qurintltler of comP h l v c r (a) Limited auantltles of compressed
8173606 Llmlled
gases for which exceptlons are permltted as noted by reference to this sect!on in t 172.101 of thls subchapter are excepted from labeling (except when offered for transportatlon by alr) and, unless repulred as a condltlon of the exceptlon. speclflcatlon packaging requirements of t h b subchapter when packed ln accordance wlth the followhe paramaphs. In addltlon, shlpments are not subject to Subpart F of Part 172 of t h b subchapter, to Part 174 of t h b subchapter except I174.24 and to Part 177 of thL subchapkr except 0 177.817. (1) When in containers of not more than I nuld ounces capaclty (7.22 cubic Inches or less) except clgarette Ilghters. Speclal exceptlons for shlpment of certain compressed gases in the ORM-D class are provlded In SubPart N of t h b part. (2) When ln metal containers filled with a material that Is not classed as a hazardous materlal to not more than 90 percent of capacity a t 70' F. then charged with nonflammable, nonllquefled gas. Each container must be tested to three times the pressure at 70' F. and, when refllled. be retested to three times the pressure of the gas a t 70' F. Also. one of the followlng condltlons must be met: (1) Container Is not over 1 quart caPacity and charged to not more than 170 pslg a t 70' E and must be packed In a strong outslde packaging, or (11) Container Is not over 30 gallons capacity and charged to not more than 75 pslg at 70' F. (3) When ln a metal contaher charged with a solution of materials
8 173.306
and compressed gas or gases whlch is nonpolsanous, provlded all of the following condltlons are met. Speclal exceptions for shlpment of aerosols In the ORM-Dclass are provlded In Subpart N of thls part. (1) Capaclty must not exceed 50 cubic inches (27.7 nuld ounces). (11) Pressure In the contalner must not exceed 180 pslg at 130' F. If the pressure exceeds 140 pslg at 130' F.. but does not exceed 160 pslg at 130' F.. a speclflcatlon DOT 2P ( # 178.33 of thls subchapter) Inslde metal contalner must be used; If the pressure exceeds 160 psig at 130' F.. a speclflcation DOT 2Q ( 8 178.33a of thls subchapter) iwlde metal contalner must be used. In any event, the metal container must be capable of wlthstandIng without burstlng a pressure of one and one-half times the equllibrlum pressure of the content at 130' F. (lit) Llquld content of the material and gas must not completely fill the container at 130' F. (tv) The container must be packed in strong outslde packaglngs. tv) Each completed container filled for shlpment must have been heated until the pressure in the contalner Is equlvalent to the equlllbrlum pressure of the content at 130' F. (55' C.) without evidence of leakage, distortion. or other defect. (VI) Each outslde packaglng must be marked "INSIDE CONTAINERS COMPLY WITH PRESCRIBED REGULATIONS." (b) Ezemptions for /oodslrcf/s, soap, biologicals, electronic tubes, and audible fire alarm system. Llmlted quantltles of compressed gases, (except polsonous gases as deflned by # 173.326) for whlch exceptlons are provlded as lndlcated by reference to this section In 0 172.101 of thls subchapter, when In accordance wlth one of the following paragraphs are excepted from labellng (except when offered for transportatlon by alr) and the speclflcatlon packaging requirements of this subchapter. In additlon. shipments are not subject to Subpart F of Part 172 of this subchapter, to Part 174 of this subchapter except 4 174.24 and to Part 177 of this subchapter, except 5 177.817. Special exceptions for shlpment of certain compressed gases in
143
144 Alternative Formulations and Packaging to Reduce Use of CFCs
5 173.306 the ORM-D class are provlded In Subpart N of this part. (1) Foodstuffs or soaps in a nonreflllable metal container not exceeding 50 cublc inches capacity (27.7 fluld ounces), wlth soluble or emulslfled compressed gas. provlded the pressure in the container does not exceed 140 p.s.1.g. a t 130' F. The metal contalner must be capable of wlthstandlng wlthout bursting a pressure of one and one-half times the equllibrlum pressure of the content at 130' E (1) Containers must be packed in strong outslde packagings. (11) Liquid content of the material and the gas must not completely fill the container at 130' F. (HI) Each outside packaging must be marked "INSIDE CONTAINERS COMPLY WITH PRESCRIBED REGULATIONS." (2) Cream in refillable metal receptacles wlth soluble or emulsifled compressed gas. Containers must be of such deslgn that they will hold pressure without permanent deformatlon up to 375 pslg and must be equipped with a device designed so as to release pressure without bursting of the container or dangerous projection of its parts at higher pressures. This exception applies to shipments offered for transportation by refrigerated motor vehlcles only. (3) Nonrefillable metal containers charged with a solution containing blological products or a medical preparation whlch could be deterlorated by heat, and compressed gas or gases. which is nonpoisonous and nonflammable. The capacity of each container may not exceed 35 cubic inches (19.3 fluid ounces). The pressure in the container may not exceed 140 pslg at 130' F.,and the Uquld content of the pro&uct and gas must not completely fill the containers at 130' F.One completed container out of each lot of 500 or less, fllled for shipment, must be heated, until the pressure in the contAner is equivalent to equllibrium pressure of the content at 130' F. There must be no evldence of leakage, distortion. or other defect. Container must be packed in strong outside packagings. (4) Electronlc tubes, each having a volume of not more than 30 cublc
49 CFR Ch. I (10-1-89 Edition)
Inches and charged wlth gas to a pressure of not more than 35 pslg and packed In strong outslde packag,ings. (5) Audible flre alarm systems powered by a compressed gas contained In an inslde metal container when shlpped under the following condltlons: (1) Each h i d e contalner must have contents which are not flammable, polsonous. or corroslve BS deflned under this part, (11) Each inslde contalner may not have a capaclty exceeding 35 cublc inches (19.3 fluid ounces), (Ill) Each inslde container may not have a pressure exceedlng 70 pslg at 70' F. and the 1lquld portlcn of the gas may not completely flll the inslde contalner at 130' F..and (lv) Each nonreflllable lnslde container must be designed and fabricated with a burst pressure of not less than four tlmes Its charged pressure at 130' F. Each refillable inside container mi!& be designed and fabrhated with a burst pressure of not less than flve times its charged pressure at 130' F. tc) Fire atinguishers. Mre extinguishers charged with limited quantltles of a compressed gas to not more than 240 pslg a t 70' F. are excepted from labellng (except when offered for transportation by air) and the speclflcatlon packaging requlrements of this subchapter when shipped under the followins conditions. In addltlon, shlpments are not subJect to Subpart F of Part 172 of this subchapter, to Part 174 of this subchapter except 5 174.24 and to Part 177 of this subchapter except 0 177.817. (1) Each fire extlngulsher must be shipped as an Inslde packaging; (2) Each flre extinguisher must have contents which are not flammable. poisonous, or corroslve as deflned under this part; (3) Each flre extlngulsher under stored pressure may not have an Internal volume exceeding 1,100 cublc Inches. For fire extlnguishers not exceedlng 35 cublc inches capacity, the llquld portion of the gas plus any addltlonal llpuld or solld must not completely fill the container a t 130' F. Fire extlngulshers exceeding 35 cublc lnches capacity may not contain any llquefled compressed gas;
Appendix B-DOT Regulations for Compressed Gases
Research and Special Programs Administration, DOT
5 173.306
(4) Each fire extinguisher manufac- or other compressed gas fuel tanks, tured on and after January 1, 1976, provlded such tanks are securely must be designed and fabricated with closed, are not subject t o any other rea burst pressure of n o t less than six quirements for transportatlon by rail times It0 charged pressure at 70' F. or highway. F o r transportation by water, see 9 5 176.905 and 178.78(k) of when shipped. (5) Each fire extlnguisher must be this subchapter. For transportation by tested, without evidence of failure or air. t h e fuel tank must be removed or damage, to a t least three times I t s emptied and securely closed. charged pressure at 70' F. but not less (3) A cylinder whlch Ls a component than 120 pslg before Inltlal shipment. part of a passenger restralnt system For any subsequent shlpment. each and is lnstalled In a motor vehicle, flre extinguisher must be in compll- charged wlth nonliquefied. nonflamance with t h e retest requirements of mable compressed gas and having no t h e Occupational Safety and Health more t h a n two actuating cartrldges Administration Regulations of the De- per valve, Ls excepted from t h e repartment of Labor, 29 CFFt q u i r e m e ~ t sof Parts 170-189 of this 1910.157te). and; subchapter except: (6) Each flre exth;guisher must be (1) Unless otherwise authorized by marked t o indicate t h e year of t h e test t h e Department, each cylinder must (withln 90 days of the actual date of be ln compllance wlth one of t h e cylint h e origlnal test) and "MEETS DOT der speclflcatlons In Part 178 of this REQUIREMENTS." This marklng will subchapter and authorlzed for use ln be considered a certification that the 0 173.302 for t h e gas I t contains; fire extinguisher was manufactured ln (11) Each cyllnder must be in compllaccordance with the requirements of ance wlth t h e filling requirements of thls section. 0 173.301: and (111) Each actuating cartrldge must N o m The words "This extlngulsher meets all requlrements of 49 CFR 173.306" may be be approved in accordance with dlsp!ayed In place of "MEETS DOT RE- 5 173.86 and meet the definltlon set QUIREMENTS" on extinguishers manufac- forth in 0 173.100tw). tured prior to January 1. 1978. (4) A cylinder which is part of a tire (7) When Specification 2P or 2Q inflator system in a motor vehicle, ( p i 178.33. 178.33a of this subchapter) charged with a nonliquefied. nonflampackagings are used, paragraphs mable compressed gas Is excepted tc)(rlH6) of thls section are not appll- from t h e requirements of Parts 170cable provided each packaging meets 189 of this subchapter except: t h e requirements of paragraph (a) of (1) Unless otherwise authorized by this section. t h e Department, each cylinder must (d) Truck bodies or traiIers on flat be In compliance with one of t h e cylincars; automobiles, motorcycles, frac- der specifications in Part 178 and auton, o r other self-propelled vehicles. (1) thorized for use in 5 173.302 for t h e Except as specified in 5 173.21, truck gas it contains; bodies or trailers with automatic heat(ii) Each cylinder must be In compliing or refrigerating equlpment of the ance with t h e filling requirements of gas burning type may be shipped with f 173.301. tanks containing fuel and equipment (111) Each cylinder must be securely operating or not operating, when used lnstalled in t h e trunk of t h e motor vefor the transportation of other freight hicle and t h e valve must be protected and loaded on flat cars as part of a against accidental discharge. jolnt rail-hlghway movement. The NOTE:A cylinder contalnlng a gas generaheating or refrigerating equipment is considered to be a part of t h e truck tor may be included within the provisions of exception if the repuirements of body or trailer and is not subject to this D 173.34tdl are satisfled. any other requirements of this sub(e) Refrigerating machines. (1) New chapter. ( 2 ) Automobiles, motorcycles, trac- (unused) refrigerating machines or tors, or other self-propelled vehicles components thereof a r e excepted from equipped with liquefied petroleum gas t h e speciflcstion packaging require-
145
146
Alternative Formulations and Packaging to Reduce Use of CFCs
9 173.1200 ORM-D materlal (see 0 173.500) provided that an ORM-Dexception Is authorized in speclflc sectlons applicable to the materlal, and that it la prepared in accordance wlth the following paragraphs. (The gross welght of each package must not exceed 65 pounds and each package offered for transportatlon aboard aircraft must meet the requirements of 173.6.) (1) Flammable Liquids m w t be: (1)
In Inside metal containers, each having a rated capacity of 1 quart or less, packed in strong outslde packagings. (11) In Inslde contalners, each having a rated capaclty of 1 pint or less,
packed in strong outside packaglngs. (111) I n inside contalners, each having a rated capaclty of one gallon or less, packed in strong outslde packagings. The provlslons of thls exceptlon apply only lf the flash point of the materlal Is 73' E or higher. (2) Corrosive liquidr must be: (1) I n bottles, each having a rated capaclty of 1 p h t or less, each enclosed in a metal can, packed In strong outslde packaglngs. (11) In metal or plastlc containers, each having a rated capaclty of 1 pint or less, packed in strong outslde packagings.
(111) In metal or plastic Inslde containers. each having a rated capacity of not over 1 quart, packed in strong outslde packaging provlded the liquid mixture contains 15 percent or less corroslve materlal and the remainder of the mlxture does not meet the deflnltion of a hazardous material as defined In this subchapter. Not authorbed for transportatlon by air. (3) Corrosive solids must be: (1) In earthenware, glass, plastic or paper containers each havlng a net weight of 5 pounds or less, packed in strong metal, wooden, or flberboard outside packaglngs. each havlng a net welght of 25 pounds or less. (11) In metal, rigid fiber, or compositlon cans or cartons or rigid plastic containers each havlng a net welght of 10 pounds or less, packed In strong outside packaglngs each having a net weight of 25 pounds or less. CUI) In metal, rldd flber. or composltion cans or cartons or rlgid plastlc contalners, each having a rated capac-
49 CFR Ch. I(l0-1-89 Edition)
ity of not over 20 pounds, Overpacked in metal, wooden or flberboard Outside containers not exceeding SO porn& net welght provlded the rolld mixture contalns 10 percent or less co~oslve materlhl and the remainder of the mfxture does not meet the definitlon of a hazardous material BP defined thla subchapter. (4) Flammable soli& except for charcoal brlquettes must be In hide containers each having a net welght of 1 pound or less, packed In strong out. slde packaglngs each having a net welght of 25 pounds or less. Charcoal brlquettes may be shipped in packag. Ings having a net welght of 65 pounds or less. (5) Ozfdizers must be in Inside containers each having a rated capacity of 1 pint or less for llqulds or a net weight of 1 pound or less for sollds. packed in strong outside packaging each havlng a net welght of 2s pounds or less. (6) Organic permides must be: (1) In inslde containers whlch must be securely packed and cushloned with noncombustlble cushlonlng materlal In strong outslde packaglngs contalning not over 1 p h t or 1 pound net quantlt y of the materlals. Cushlonlng Is not requlred when the liquid Is contained In strong, securely closed, plastic packaglngs, not over 1 ounce capaclty each. properly packed to prevent leakage or breakage. (Ii) In strong outslde packaghgs of 24 or less lnslde flberboard containers. each having 70 or less securely closed tubes having a maxlmum fluid capacity of %-ounce each and securely packed In noncombustlble cushioning materlal. Each flberboard contalner may not contaln more than 1 pint of llquld. (7) Poison B liquids or soli& must be in lnslde containers, each having a rated capacity of 8 ounces or less by volume for llqulds or of 8-ounces or less net welght for sollds packed In strong outslde packagings. (8) Compressed gases must be: (1) In inslde containers, each havlng a water capacity of 4-fluld ounces or less (1.22 cubic inches or less), packed in strong outslde packagtngs. (11) In inslde metal contalner charged with a solutlon of materlals
Appendix B-DOT Regulations for Compressed Gases
peroarch and Spocial Programs Administration, DOT
a d compressed gas or gases whlch Is .onpolsonous. meeting all of the foliowing. (A) Capaclty may not exceed 50 cubic inches (27.7 fluld ( 8 ) Pressure in the container may not exceed 180 p.s.1.g. at 130' F. (55' c.). If the pressure exceeds 140 p.s.i.g. at 130' F., (55' C.) but does not exceed 160 p.s.1.g. at 130' F.. (55' C.) a apeclflation DOT 2P (fi 178.33 of this subchapter) Inside metal container must be used; If the pressure exceeds 160 pa.1.g. a t 130' F.. (55' C.), a speclflcation DOT 2Q ( f 178.33a of this subchapter) inslde m e w container must be used. In any event the metal conLaher must be capahle of withstandh g . wlthout bursting. a pressure of one and one-half times the equilibrlum pressure of the contents at 130' F. (55' C.X (C) Liquld content of the material and gas not completely fill the container at 130' F. (55' C.); (D) The containers must be packed In strong outslde packagings; and (E)Each completed contalner filled for shipment must have been heated until the pressure in the container Is equivalent to the equilibrium pressure of the content at 130' F. (55' C.) without evidence of leakage. dlstortlon, or other defect. (111) In a non-refIUable inslde metal container of 50 cublc-inch capaclty or less (27.7 fluid ounces). with foodstuffs or soaps and wlth soluble or emulsified compressed gas. provided the pressure In the contalner does not exceed 140 p.s.1.g. a t 130' F. (55' C.). The metal container must be capable of wlthstanding, without bursting. a pressure of one and one-half times the equllibrlum pressure of the contents at 130' F. (55' C.) and must comply wlth the following provlslons: (A) Containers must be packed in strong outside packagings, and (B) Liquld content of the material and gas may not completely fill the container at 130' F. (55' C.). (lv) In refillable inslde metal containers with cream and soluble or emulsifled compressed gas packed In strong outslde packagings. Containers must be of such design that they will hold pressure without permanent deformation up to 375 p.s.i.g. and must
8 173.1200
be equlpped with a device designed so BS to release pressure without bursting of the contalner or dangerous projection of I t s parts at hlgher pressures. tv) In non-refillable Inslde metal containers charged wlth a solution, containing biological products or a medlcal preparatlon whlch could be deterlorated by heat, and compressed gas or gases whlch Is nonpolsonous and nonflammable. The capaclty of each container may not exceed 35 cublc Inches (19.3 fluid ounces). The pressure in the container may not exceed 140 p.s.1.g. a t 130' F. (55' C.), and the liquld content of the product and gas may not completely fill the container at 130' F. (55' C.). One completed container out of each lot of 500 or less, filled for shipment, must be heated, until the pressure in the container is equivalent to the equilibrlum pressure of the content at 130' F. (55' C.). There may be no evldence of leakage, dIstortlon, or other defect. Container must be packed in strong outside packaghgs. (VI) In electronic tubes, each having a volume of not more than 30 cublc inches and charged withb 'as to a pressure of not more than 35 p.s.1.g. and packed In strong outside packagings. tvii) In an Inslde metal container as a component of an audlble fire alarm system powered by a compressed gas meeting the followlng provislons: (A) Each Inside container must have contents which are not flammable, polsonous. or corrosive as defined under thIs part; (B) Each Inside contalner may not have a capaclty exceeding 35 cubic inches (19.3 fluld ounces); (C) Each Inslde container may not have a pressure exceeding 70 p.s.1.g. a t 70' F. (21' C.) and the llquld portion of the gas may not completely flll the inside container at 130' F. (55' C.); (D)Each hide contalner must be designed and fabricated wlth a burst pressure of not less than flve times I t s charged pressure at 130' F. (55' C.); and (E) Each fire alarm system must be packed in a strong outslde packaging. [Amdt. 173-94. 4 1 FR 16091. Apr. 15. 1976. as amended by Amdt. 173-94.4 41 FR 10684.
147
(SI) Conversion Factors
Appendix C-Metric To
Qunntiry
Convert Form
To
in ft
Length:
CP
m
’a’
Area: Volume :
ED’
ft’
m1
in’
CP’
m’
f t’ I3.L
m’
Lb
,ynSs (wight):
kg kg
02
short ton (ton) 4 5 short ton (ton) metric ton (t)
Pressure :
atm
= Hg Psi.$ Psis T
Temperature:
kPa kPa kPa Ha‘ ‘C*
K‘
*C BWb
Caloric Value: Enthalpy:
i3tU/lbwl kd/gnOl
BW1b-T
Specific-Heat Capac i cy: Densi cy :
lb/fr’ Ib/& =/gal
Cancencrarion:
qunrtwgal grl/min
Flowrace:
&/&Y
Velocity: Viscosity:
wh8 W h P l W h P l u / k g ‘C
-
kg/m’
kg/m’ kg/d cm’/m’ m’/min
m’/&y ft’/min m’/min f t/min m/dn centipoise (CP) Pa-s (kg/m-s)
'Calculate as indicated
148
Multiply By
2.56 0.3068 6.6516 0.0929 16.39 0.0283 0.0038 0.4536 0.0283 0.9072 0.9072 101.3 0.133 6.895 ((psig)+14.696)~(6.895) (5/9)x(”F-32) ‘C+273.15 2.326 2.326 4.186 6.1868 16.02 119.8 25.000 0.0038 0.0038 0.0283 0.3068
0.001
Part II Alternative Formulations and Aerosol Dispensing Systems The information in Part II i s from Aerosol Industry Success in Reducing CFC Propellant Usage, prepared by Thomas P. Nelson and Sharon L. Wevill of Radian Corporation for the US. Environmental Protection Agency, November 1989.
149
1. Introduction There is an urgent need to reformulate aerosol products into compositions that no longer contain chlorofluorocarbons (C,Cl,F,).
As early as 1973,
scientists recognized that these compounds had very long atmospheric lives and could ultimately penetrate the stratospheric ozone layer at altitudes of betveen about 14 to 27 km.
Once in the stratosphere, C F C s are bombarded with
high-energy radiation from the sun, splitting off a chlorine atom that reacts with thousands of ozone molecules and reduces them to ordinary oxygen. Although the ozone is reformed by natural processes over time, the overall effect is of ozone depletion. During September 1987. a meeting held in Montreal, Canada vas attended by representatives of many nations. A treaty known as the Montreal Protocol was developed calling for the orderly reduction of chlorofluorocarbon (CFC) production, roughly according to the folloving schedule: By July 1. 1989
Reduction to the 1986 average production Level [15-
25% actual reduction in the U.S. because of the growth in CFC use since 1986; Ozone Depletion Potential (ODP) basis.]
By July 1, 1993
Reduction to 80% of the 1986 average level. ODP basis.
By July 1, 1998.
Reduction to 50% of the 1986 average level, ODP Basis.
151
152
Alternative Formulations and Packaging to Reduce Use of CFCs
As of October 1989, the treaty had been ratified by 43 nations plus the European Community (EC) as a bloc, which together produce approximately 90% of the world tonnage of CFCs. The results of stratospheric studies made after the Montreal Protocol now
strongly suggest that the reduction plan is insufficient to prevent a further depletion of ozone. Another problem has surfaced, however. As CFCs are phased out, they will be replaced by such chemicals as HCFC-22. 1,l.l-trichloroethane(methyl chloroform) and similar substances, many of which can also deplete stratospheric ozone. Table 1 provides comparative figures.
In 1985. HCFC-22 was responsible for only 0.4% of ozone removal, while 1.1.1-trichloroethanecaused about 5.1% ozone removal and CFC-12 was responsible for about 40.1% of the total ozone removal caused by the compounds listed in Table 1. Except for the hydrocarbons and nitrogen, all the compounds in Table 1 are anthropogenically produced. Such compounds as HCFC-123, HCFC-124, HFC-134a. and HCFC-14lb are currently undergoing extensive toxicological testing that is expected to continue until about 1992. HCFC-123 currently has an Acceptable Exposure Limit (AEL). or TLV, of 100 ppm, but this may be changed to somewhere in the
SO to LOO ppm range as further results are developed. Similarly, HCFC-14lb may get an AEL of 100 to 300 ppm. Results of the Ames Salmonella Test for HCFC-22. HCFC-14lb. and HCFC-142b show positive mutagenic results for all the compounds, but extensive animal testing has clouded the meaning of the Ames results.
Introduction
TABLE 1.
COlpOund CFC-11 CFC-12 CFC-113 CFC-114 CFC-115
153
EMISSIONS AND OZONE DEPLETION POTENTIALS OF AEROSOL PROPELLANTS AND RELATED COMPOUNDS
Structure
1985 b i s i o B Ik t o a s / w )
Ozone Depletion Potential (ODP) (CFC-11 = 1)”
281 307 138
1.00 1.0 0.8 0.8 0.4 (0.i5)b
ELF CUJ-CtlP, CUF7-CClF, cc1F,-CF,
(low1 (very low)
ECFC-22 ECFC-123 YCFC-132b HCFC-124 HFC-134a XFC-iB BCFC-14ib HCFC-142b EFC-152a
lalon 1211 lalon i301 lalon 2402
VNEP 3ata of 18-03-1988.
‘Isahen, et a1 (1988). ‘Yp can destroy stratospheric ozone but its ODP is undefined.
0.05 0.02 0.05 0.02 0 0 0.10 0.06 0
2.1 10.0 5.6
154
Alternative Formulations and Packaging to Reduce Use of CFCs
Many of the future alternative compounds are nonflammable. while others are flammable.
HCFC-123 is nonflammable. but a mixture of this gas and 8.8%
isobutane is marginally flammable.
HCFC-141b has a flammable range of 6 . 4 to
15.1%. while HCFC-142b’s flammable range is 6.7 to 14.9%.
HFC-l34a, which is
being groomed as a replacement for most uses of CFC-12, is nonflammable. HCFC-22 is the only n o n f l m l e (l), commercially available CFC alternative that the industry vi11 have until about 1993 or 1994, when some or all of the second generation CFC alternatives should come onto the market.
It is only
marginally nonflammable; the addition of 6% isobutane, or 8.6% ethanol to HCFC-22 will produce mixtures of borderline flammability. The vorldwide aerosol business is highly diversified. In 1989, the U . S . will produce about 3 billion units (95% non-CFC aerosols), or 35% of the world total of about 8.6 billion units.
Western Europe will produce about 39%.
Japan 5 % . Brazil 2X, and Mexico 0.5%. Per capita usage is 11 units per person in the U.S.: the typical home contains 46 aerosol products, averaging 206 g per unit.
Since the purchase of aerosols is often discretionary (they are not
generally considered to be utility products) the per capita usage in different countries is a reflection of both availability and of the relative standard o f living.
The more hours a person must work to purchase an aerosol, the fewer
vi11 be purchased. Apart from the usual competitive pressures, there is a strong motivation to reduce the costs of aerosol products in order to increase sales.
In the
U.S.. hydrocarbon propellants cost less than 20% of the rapidly escalating costs of CFCs.
They are therefore the propellants of choice unless special
properties are required, such as better solvent action or reduced flammability. Approximately 81% of U.S. aerosols are pressurized with propane, n-butane, isobutane. or their blends.
Another 7% use carbon dioxide,
and the remaining 12% use nitrous oxide, CFCs, dimethyl ether, nitrogen, HFC152a and HCFCs. in approximately that order.
The few CFC aerosols remaining
after the general ban on these products was imposed during 1978 are those permitted by exclusion, exemption, or those that are not regulated.
Introduction
155
Hydrocarbon propellants are already in wide use throughout the world.
Examples are as follows: United Kingdom, a market share of 30%; West Germany, 80%; Brazil. 88%; Mexico, 92%; and Canada, 78%.
The next preferred CFC
alternative is dimethyl ether (DHE, or dimethyl oxide).
DME alternatives are
about 10% more costly than the hydrocarbon alternatives in Western Europe,
100% more expensive in the U S . , and even more costly. or unavailable, in other parts of the world. The major producers are Western Europe, with a capacity of 60,000 tons, Japan, the U.S., Canada, and Australia. ether is flammable.
Dimethyl
It is also a very strong solvent, sometimes causing
gasket failures in equipment. aerosol corrosion, valve seal leakage, and excessive swelling of some elastomers.
It is highly water soluble, and can be
used as a way of incorporating water into solution in selected aerosol products. such as hair sprays and personal deodorants.
Table 2 compares che
physical properties of the non-CFC aerosol propellants. Although carbon dioxide, nitrous oxide, and nitrogen are widely available throughout the world, they have either been ignored or little used as aerosol propellants.
These gases are inexpensive, but special equipment is often
required to add them to aerosol containers. The simplest of these is the gasser-shaker, of either in-line or rotary construction. which is shaken at a preset frequency and amplitude for a fixed period of time.
It is connected
through the valve to a supply of gas regulated to a pressure of approximately 142 to 178 psig (10.0 to 12.5 bars).
Valve designs are available that will
facilitate gas flov into the can, even with the button attached.
Since the
quantity of gas added will be in the range of 3 to 28 g. depending on can size and content. the weight increase of the dispenser is used as a basis for machine adjustments.
Table 3 shows the potential uses of these propellants
for several representative products. HCFC-22 is widely used throughout much of the world as a specialty refrigerant and freezant. Despite its nonflammability (1) and relatively low price (five times more costly than hydrocarbons, in the U.S.). it is not much used.
It is limited by its high pressure, which makes it necessary to use 40%
Alternative Formulations and Packaging to Reduce Use of CFCs
156
TABLE 2.
PHYSICAL PROPERTIES OF NON-CFC AEROSOL P R O P E L M T S
6.70 7.02 18.17
0.580
-42
1.20 2.17 7.60
0.503
2.2 -
-25
4.43
12.40
0.661
3.3
-
-41 -10
8.52
20.92
2.04
-25
4.42
6.07 12.36
1.208 1.123 0.911
6.7 3.9
-
-2
Ilbut.De
iaObYt.De
-11
Propas
BcF+-u
Bcpc-142b m-152.
Carboa Dioxide Nitroua Orid. Nlbr0i.n
-78 -88 -155
58.45
N/A
52.47 N/A
N/A
0.721 0.718
N/A
N/A
3.22
-
Bcpc-121 KFC-124
c&clz-CF3 CBClF-CF3
20 -11
m-125 BIC-134. fUFC-14lb
cBp2-c13 Q2F-CF3 CE3-CcI2F
-95 -32 33
N/A
-
0,559
Nan Applismble. abov. Critical T.mperatur.
-0.2
'
NIA
5.47 -0.3
1.7 8.8 N/A
14.3 1.2
1.470 1.368 N/A 1.203 1.231
1.8
8.6
1.8
8.5 9.5 18.0
3
:r 3 16.9
0 3 0
0
6.b
-
15.1
Introduction
TABLE 3.
157
PRODUCT APPLICATIONS OF CARBON DIOXIDE, NITROUS OXIDE, AND NITROGEX
Hydroalcoholic disinfectant/deodorant sprays. Bug killers: Ant and roach killers Wasp and hornet killers Lubricants. Anti-statics. soil repellants, and wrinkle removers for textiles. Nitrous Ox idg Whipped creams. Heavy-texture specialty foams. Windshield and car lock de-icer sprays. Furniture polish. Nitroeen Sterile saline solutions for rinsing contact lenses. Long-range. stream-type wasp and hornet killers. Injector-type engine cleaners. Over-pressurant for selected meter-sprayed vitamins and drugs
158
Alternative Formulations and Packaging to Reduce Use of CFCs
or less in formulas and to include suppressive solvents or other propellants to keep the aerosol pressure from being excessive.
An interesting blend af
HCFC-ZZ/HCFC-l&Zb (40:60) is nonflammable and has a pressure of 63 psig at
70'P
( 4 . 4 3 bar at 2l'C).
colognes.
It has been coramercialized for perfumes and
HCFC-22 is a good solvent.
At less than 28% propellant, its
ethanol solutions are lower in pressure than those of CFC-12 and ethanol. HCFC-142b is used in a few applications in the U.S. and is presently unavailable elsewhere.
It is now made by only one supplier, although a second
supply source is being developed.
As the methyl homolog of HCFC-22, it has
many properties in common with the parent compound, except the high pressure. It is more than 12 times as costly as hydrocarbon propellants in the U.S., which has restricted its aerosol applications. HFC-152a is close to an ideal propellant, except that it is flammable. It is less flammable than hydrocarbon gases, however, and it has typically been used with 70% A 4 6 (20 mol X propane and 80 m o l % isobutane) to produce a propellant for shave creams, depilatories. and mousse products whose foam surface will not momentarily flash if a lighted match is touched to it. The composition is as follows: 60.9% Isobutane 9.1% Propane 30.0% HFC-152a
Since the pressure of the aerosol is about 154 psig at 130'F
(11.0 bar at
55"C), according to the partial pressure of remaining air, an extra-strength can is needed. HFC-152a is noted for its exceptionally lov odor and good solvency.
It
is used to make less flammable colognes and perfumes, especially for those essential oils chat might eventually precipirate high-molecular weight resins, fonds, or substantives in rhe usual ethanolfiydrocarbon (or pure hydrocarbon) systems.
Finally, it can be used with many surfactant systems,
Co
partly
destabilize aerosol foams, permitting them to be more readily rubbed out on
introduction
159
surfaces and not resist liquefaction. A typical product that uses this property is baby oil mousse, which contains 20 to 30% mineral oil.
In the U.S., since HFC-152a is approximately eight times the cost of hydrocarbon propellants, the amounts used in formulas are generally in the 2 to 10% range.
It is available in the U.S. and Western Europe. and suppliers
claim that distribution systems will be set up to greatly increase world access to this propellant and to HCFC-142b. The future "CFC alternative" propellants identified in Table 2 are presently undergoing acute, sub-chronic, and chronic (lifetime) toxicological testing. To date, the results have shown some variation in relative toxicity. but indications are that all five compounds will probably be approved for commercial use.
The official toxicological reports will be issued in 1992 and
1993. but plans are now in motion to build production facilities well before that time.
In the U.S.. W o n t has announced that an existing commercial plant is being converted to produce HCFC-14lb and HCFC-142b in 1989. A new plant has been approved to produce large quantities of HFC-134a by 1990. Large quantities of HCFC-123 are already available as a co-product from an existing DuPont facility. And during 1988 DuPont was issued a U.S. Patent on new technology aimed at coproducing HCFC-123 and HCFC-124 in a single process. No schedules for HCFC-124 production have been published. Other CFC suppliers in the U . S . , Western Europe, Japan, and other parts of the world are also studying their options for phasing out CFCs and
commercializing various alternatives. The major alternative will probably be HFC-134a. since it will be used to replace CFC-12 in refrigeration, freezant. and air conditioning systems. An
accelerated CFC phase-down program. which goes beyond the Montreal
Protocol and is now supported by numerous countries, is based on rapid commercialization and application of the HCFC and HFC alternatives. The science centers around minimizing furrher increases in the chlorine content of the stratospheric ozone layer.
Alternative Formulations and Packaging to Reduce Use of CFCs
160
Table 4 lists the aerosol products currently exempted or excluded from the general regulatory bans in the U.S. on CFCs for aerosol uses. They serve life-saving or other medical purposes. or are considered "essential for other reasons." A
few of these products have been discontinued, such as the drain openers
and small-size tobacco barn sprays. The largest users of CFCs are the mold release agents, lubricants. and meter-spray inhalant drug products, except for CFC-12 and CFC-114 small refrigerant recharge units, which many people do not consider to be true aerosol products. When considering propellants or propellant/solvent combinations that may be used for reformulating CFC aerosols, a large number of attributes must be evaluated. Flammability, toxicology, solvency, cost, availability, solvate formation, solvolytic stability, dispersancy. pressure, and compatibility are some of the more essential characteristics. In the late 1980s. a growing intolerance developed towards propellants and other chemicals that have even slight effects on the stratospheric and tropospheric ecosystems, that have greater perceived toxicity than alternatives, or do not degrade in landfills.
Introduction
161
TABLE 4. EXEMPTED, EXCLUDED, OR NONREGULATED CFC AEROSOL PRODUCTS (U.S.) Mold release agents - - €or molds making rubber and plastic items Lubricants for use on electric or electronic equipment Lubricants for rotary pill and tablet making presses Solvent dusters, flushers. degreasers and coatings for electric or electronic equipment Meter-spray inhalant drugs: a. Adrenergic bronchodilators b. Cortico steroids c. Vaso-constrictors - ergotamine tartrate type Contraceptive vaginal foams - for human use Mercaptan (as ethyl thiol) mine warning devices Intruder audio-alarm system canisters for house and car uses Flying insect sprays: a. For comercial food-handling areas b. For commercial (international) aircraft cabin sprays c. For tobacco barns d. For military uses Military aircraft operational and maintenance uses Diamond grit abrasive uses For uses relating to national military preparedness CFC-115 as a puffing (foaming) agent in certain food aerosols Automobile tire inflators Polyurethane foam aerosols Chewing gum removers Drain openers Medical chillers - for localized operations Medical solvents - as a spray bandage remover Dusters for non electric or electronic uses - for phonograph records and computer tapes Cleaners for microscope slides and related objects Foam. whip, or mousse products in general Small refill units for refrigeration or air-conditioning systems All other 100% CFC product applications
-
-
2. Formulation Guidelines GENERAL CONSIDERATIONS
Dispersancy, one major attribute of aerosol propellants, is the efficiency with which a propellant can produce a fine spray or an acceptable foam. h i s is illustrated in Table 5. The dispersancy of blends can be readily calculated.
For example,
Propellant A 4 6 (20 mol% propane and 80 m o l % isobutane) has a dispersancy of [549 X . 2
+ 415 X .8]
- 442
mL/g at 21.1'C.
A shave cream or mousse. made using either 8% CFC-l2/114, 4% A - 4 6 , or 2% nitrous oxide will all show the same properties of foam density and overrun. (However. the nitrous oxide formula will have a very high pressure, which can be expected to decrease significantly with use.)
In the years before the CFC aerosol ban of 1978 in the U.S., hair sprays Were commonly formulated with 45% CFC-12/11 ( 5 5 : 4 5 ) , or 40% Propellant A (10% Isobutane. 45% CFC-12. and 45% CFC-11).
They are now formulated with 20 to
26% isobutane, sometimes with a small amount or propane added.
These examples
show the importance of dispersive effect to propellant volume. The dispersive effect i s not linear but is modified by vapor-pressure, solubility factors, and even by the pressure itself.
It normally can be used
as a general guideline to determine equivalencies when changing from one propeLlant choice t o another.
162
Formulation
TABLE
Propellant
5.
DISPERSANCY (In order
Vapor
CHARACTERISTICS of Vapor Volume
Volume
Nitrogen
(mL/g
2l.10C)
OF VARIOUS in mL/g)
Vapor
Guidelines
PROPELLANTS
Volume
(mL/mL 2l.l"C)
862
N/A
Carbon
Dioxide
549
N/A
Nitrous
Oxide
549
N/A
549
280
523
345
isobutane
415
234
nbut:ane
415
239
HFC-152a
365
333
HCFC-22
279
337
CFC-l15
256
HCFC-142b
240
269
HFC-134a
236
283
HCFC-141b
206
253
CFC-12
200
265
CFC-125
198
227
CFC-ll
176
261
HCFC-124
176
242
HCFC-123
158
232
CFC-114
141
207
FC-CJ18
119
179
Propane Dimethyl
Note: N/A-
Ether
These propellants Not Applicable
boil
at
<2l.2.C
(not
(Range:
23~C.)
available}
163
164
Alternative Formulations and Packaging to Reduce Use of CFCs
The aerosol formulator will also have to determine such things as company policy, availability of equipment, and the safety features of the workplace. Nonflammable propellants (apart from CFCs) consist of nitrogen, nitrous oxide, carbon dioxide, HCFC-22, and a few blends of other propellants with HCFC-22.
Future nonflammable propellants will consist of HCFC-123, HCFC-lZL,
HCFC-125, and HFC-134a. worldwide.
Of these, HFC-134a may become available most quickly
The cost of HCFC and HFC propellants is expected to be about
twenty times that of purified hydrocarbons by 1993 or 1994; this may limit their application to relatively specialized products, for example. to perfume meter-sprays in container sizes of 50 mL or less.
When flammable propellants are considered to be within the scope of company operations, the most reasonable choices are isobutane and propane. some parts of the world the "natural blend" must be used.
In
A typical natural
blend will consist of 60% nbutane, 20% isobutane, and 20% propane.
It is a
broad distillation cut from the gas wells after de-ethanization and partial de-propanization.
In some areas, the hydrocarbon may contain large amounts of
other impurities.
Some gas wells in Canada vere found to contain over 50%
hydrogen sulfide and alkyl mercaptans (thiols), causing their closure.
Wells
in Trinidad typically contain 12% unsaturates, such as propylene and isobutylene, making them marginally useful for aerosol applications. Propanefiutanes from gas wells in Brazil contain 2.5 to 5 . 5 % unsaturates. Any contract filler or self-filler contemplating a change from CFC to hydrocarbon propellants should thoroughly investigate such things as availability, purity, fire and building codes or regulations, the cost o f conversion. such as the construction of an outside gas house, safety equipment, and electrical revisions. The product development and quality control laboratories should be equipped with explosion-proof hoods. ventilation. and other safety equipment. When available, dimethyl ether offers a relatively inexpensive alternative to the hydrocarbon propellants.
It does not have the potential
165
Formulation Guidelines
problem of odor.
It is less flammable (on an absolute, LEL. or other scale)
but it is also a very scrong solvent. The flamable HCFCs and HFCs are final options, but because of their relatively high cost they may have a minor effect on the vorldwide aerosol indus try.
Most concentrates are available in the form of suggested formulacions by ingredient suppliers. They may be made especially for aerosol uses, or they may be adaptable to aerosol applications.
Some, like most paint products,
have to be drastically altered before they will vork for aerosols. A large collection of supplier samples and literature is a requisite of any formulacing laboratory. The literature should cover properties, uses, compounding techniques, toxicological data and suggested prototype or starting formulations.
(Sometimes these formulas have somewhat more of the supplier's
product than is really needed.) After a concentrate has been tentatively developed, there remains the process of adding the correct type and amount of propellant, and using an aerosol valve that will develop the desired spray pattern or foam puff.
One
of the mast important characteristics that the formulator looks for is
particle size distribution, which can be of paramount importance.
If the
droplet size is too coarse. it can be decreased by one of the following techniques:
0
Increase the percentage of propellant;
0
Increase propellant pressure and/or dispersancy;
0
Use a vapor-tap valve or a larger vapor-tap orifice;
0
Use a mechanical break-up button;
Alternative Formulations and Packaging to Reduce Use of CFCs
166
0
Add a low-boiling (volatile, easy breakup) solvent; and
0
Reduce the quantity of polymers, thickeners, resins, adhesives, and water.
Approximately 40-50% of the world's 8 billion aerosol products use vaportap valves.
Such valves have an orifice extending through the side or bottom
wall of the valve body and into the head space area.
When the orifice of a
vapor-tap valve is enlarged to decrease particle size, a price is paid.
The
negative effects are listed below:
0
A broader particle size distribution will generally result.
0
A gradual coarsening of the spray may occur during use.
0
The internal pressure will decrease, as air and the more volatile propellant ingredients preferentially escape through the vapor-tap orifice.
0
The delivery rate will always be lower than without a vapor-tap, and will decrease during use, because of pressure reduction.
The potential problems with vapor-tap valves can be minimized by the following techniques:
0
Use the smallest vapor-tap hole that will suffice (a 0.25 mm s i z e may be a good starting point).
0
Use a fairly large to large amount of propellant that disperses w e l l (reservoir effect).
a
Use a pure propellant; otherwise. the more volatile ingredient will be preferentially discharged. causing a pressure drop.
0
Use reasonably large liquid orifices.
Formulation Guidelines
167
Emphasize any or all of the above in taller cans, since (near
0
emptiness) a liquid column of 150
-
250 rm will have to be
maintained in the dip tube just to bring the product into the valve chamber.
A greater dynamic pressure potential is needad. compared
with shorter can sizes.
As a rule, thin or driving sprays, or sprays vith high delivery rates,
will be perceived by consumers as "wet" or *cold." although they may be anhydrous.
Wet sprays are usually disliked, except for the coating of
inanimate surfaces (such as a paint spray or bug killer); they are most disliked for cosmetic items designed to be sprayed on the skin, such as underarm antiperspirants or deodorants.
The aerosol antiperspirant provides
an interesting challenge because large vaive orifices must be used to prevent possible valve clogging by the 7 to 12% aluminum chlorohydrate powder normally present.
Here, the vapor-tap valve, used vith a mechanical break-up button,
provides a fine-particled spray. The propellant content is in the 6 8 - 8 2 2 range to give good breakup and to provide an adequate reservoir for the vaportap.
To devise a good aerosol product, a formulator must try to minimize the risks of flammability and possible explosivity.
It is a tribute to the
excellence of the aerosol packaging form that extremely flammable products can be safely dispensed, if the user follows the label directions, and if the formulator is able to make allovances for reasonably foreseeable consumer misuse.
Flammability is a potential problem when large amounts of product are
discharged at one time, as in some hair spray applications. painting, waterproofing, and in the total release insect fogger (TRIF) products. Flammability has also been a problem when containers are dropped on the valve stem, causing it to bend or crack in such a way that che valve jams, releasing a continuous spray.
Consumers have sometimes panicked and throvn the can ouc the window when this happens.
Alternative Formulations and Packaging to Reduce Use of CFCs
168
The s p e c i a l case of the TRIF product w i l l be described i n more d e t a i l later.
The l a t c h e s open on these products, allowing the e n t i r e contents of
the can, from 50 t o 400 g , t o be dispensed.
Special low-flammability formulas
a r e needed t o prevent harmful f i r e b a l l e f f e c t s if the spray is discharged too c l o s e t o p i l o t l i g h t s o r o t h e r sources of i g n i t i o n . I n t h e U.S., aerosol products are regulated according t o type by t h r e e f e d e r a l agencies.
P e s t i c i d e s such a s i n s e c t i c i d e s . d i s i n f e c t a n t s , h e r b i c i d e s ,
and rodenticides a r e handled by the U.S. EPA.
Household products such a s
p a i n t s . automotive products, a i r fresheners, and window c l e a n e r s , a r e handled by t h e Consumer Product Safety Commission (CPSC).
F i n a l l y , a l l food, drug,
and cosmetic products a r e under the c o n t r o l of the Food & Drug Administration (FDA).
The EPA and CPSC require flammability l a b e l i n g , according t o t e s t
method r e s u l t s ; the FDA does not.
The FDA merely s t a t e s t h a t products seen t o
be too hazardous o r t h a t a r e inappropriately labeled w i l l be seized and banned from f u r t h e r marketing.
A s a r e s u l t , approximately 7 0 % of a l l aerosol
containers i n the U.S. a r e marked "Flammable."
Another 5 2 , such a s many
anhydrous automotive products, a r e marked "Extremely Flammable."
Many h a i r
sprays, underarm products, and o t h e r FDA-regulated a e r o s o l s a r e a l s o marked "Flammable," although t h i s is not required. I n the U.S. and i n most o t h e r c o u n t r i e s , the standard t e s t method f o r flammability is the Flame P r o i e c t i o n Test.
Procedures and c r i t e r i a vary
somewhat, but a can is normally sprayed through the top t h i r d of a candle flame from a d i s t a n c e of 151 mm.
I f the spray i g n i t e s and c a r r i e s the flame
forward another 4 5 7 m m ( o r f u r t h e r ) , the product is considered t o be "Flammable." countries.
The term "Extremely Flammable" is r a r e l y used i n o t h e r I t r e l a t e s t o two r e s t s , a flashback t e s t and a closed cup f l a s h
point t e s t a t approximately -28'C.
For the product t o be marked "Extremely
Flammable," i t must f a i l both t e s t s : the f l a s h back must extend t o the a c t u a t o r a t any degree of valve opening, and the cup t e s t must i n d i c a t e a f l a s h p o i n t of l e s s than - 7 ' C . Although there a r e many shortcomings of the Flame Projection T e s t , which was devised i n 1 9 5 2 . i t has been adopted by many c o u n t r i e s .
A
number of
Formulation Guidelines
169
techniques can be used to reduce the length of the flame in the Flame Projection Test, so Chat a "Flammable" product can sometimes by "adjusted" to a nonflamnable one.
For example, hair spray marketers prefer to sell sprays
that have flame projections in the 300 to 400 mm range (thus nonflammable). However. these produccs are marketed with a "Flammable" label that is. in fact, an overspecification. Methods for reducing flame projection include the folloving options: Reduce the delivery rate;
0
Reduce particle size (smaller particles burn out more rapidly and move more slovly); Use a vapor-tap button. often with a mechanical breakup button (actually a way to reduce both delivery rate and particle size).
0
Add a nonflammable solvent, such as 1,1,1-trichloroethane or methylene chloride, or a nonflammable or less flammable propellant to suppress flammability. Present the product as a lotion, foam, mousse, whip, paste, metered dosage (spray or foam, micro or macro) so that the test is passed simply because it cannot be meaningfully applied.
A relatively new concept of flammability arose in 1979 in the U.S. when the Factory Mutual Research Corporation (owned by several insurance carriers) was asked to look into the subject of aerosol hazards in warehouses.
Tests
shoved that many aerosols exploded in fires, producing large fireballs and intense heating effects.
Sprinkle systems need to be sized to reflect very
high fuel loading. About 65% of the aerosol cans produced in the U.S. are anhydrous formulations containing flammable solvents and propellants.
These require sprinklers capable of spraying from about 3,300 liters/m2 to 4,200 liters/&
170 Alternative Formulations and Packaging to Reduce Use of CFCs
(depending on the degree of water m i s c i b i l i t y of the flammable i n g r e d i e n t s ) each minute, f o r c o n t r o l .
Extremely f a s t response vas a l s o a requirement so
that the f i r e could be c o n t r o l l e d while s t i l l i n an e a r l y s t a g e .
After a $2 m i l l i o n f i r e - t e s t i n g program vas f i n a l l y completed i n 1989,
the a e r o s o l industry p a r t i c i p a t e d i n w r i t i n g new codes and i n r e w r i t i n g o t h e r s
designed t o improve t h e s a f e t y features of warehouses, backstock s t o r a g e a r e a s , and d i s p l a y a r e a s .
After a lengthy development p r o t o c o l , these model
codes w i l l be completed and implemented i n 1991, a f t e r vhich i t is expected they w i l l be adopted by l e g i s l a t i v e and regulatory o f f i c i a l s f n l o c a l f i r e and b u i l d i n g codes.
Since the insurance companies t h a t support the new codes a r e
usually multinational. some e f f e c t s a r e already being f e l t i n Europe a s w e l l .
Kort U.S. a e r o s o l s a r e formulated t o a pressure a s low as is c o n s i s t e n t with good operational performance across the a n t i c i p a t e d temperature range o f t h e i r use. 37'C,
-
For example, h a i r sprays a r e expected t o work v e l l betveen 13'
and reasonably vell just outside these l i m i t s . Pressure l i m i t s f o r containers vary only modestly among c o u n t r i e s .
the U.S..
In
t h e s o - c a l l e d ordinary o r non-specification can is permitted t o hold
product v i t h pressures up t o 1,067 kPa abs. (9.85 bar vi11 not rupture belov 1.546 kea abs. (14.8 bar
-
-
gauge) a t 54.4'C.
gauge)..
14%and 282 higher pressure r a t i n g s a r e a l s o a v a i l a b l e a t an e x t r a c o s t .
only hold about 9% of the market.
They
Aerosols of l e s s than 118 mL capacity a r e
not regulated f o r pressure l i m i t s i n the U.S. begin t o deform a t about 65'C
It
Special cans v i t h
Most aerosol containers will
and vi11 rupture a t 75'C
o r h i g h e r , depending on
can and product.
The formulator's job is not complete vhen an acceptable product and packaging system has been developed.
Test packing is always needed t o
e s t a b l i s h data on veight loss r a t e s , can and valve compacibility, organoleptic
Formulation Guidelines
stability, etc.
171
Hundreds of sad stories could be written about new products
that were inadequately tested. and then could not be manufactured. eroded the can, demulsified. changed color or odor. were subject to microbial proliferation, grew inorganic crystals, or eventually threw down resinous precipitates in the container, swelled valves shut or partly shut, blistered
No fever than 36 cans per variable
can linings, b e c a w latent leakers, etc.
should be test packed and checked--some at about 25'C
and some at 4O'C;
some
upright and some inverted. Tinplate cans do not corrode unless at least 0.008% of free water is present.
Above about 0.250%. greater concentrations of water will have no
additional effect on the rate of corrosion, if any. Water has little effect on aluminum cans.
alcohol (C,H,OH) [ (C,H,O),Al]
In fact. its virtual absence can sometimes allow anhydrous
to attack aluminum cans to produce aluminum ethoxide Water is implicated in the well-known
and hydrogen (H,) gas.
ability of 1.1.1-trichloroethane to sometimes attack plain and lined aluminum cans, but the mechanism is still unclear.
Finally, water can facilitate
development of high pH values in hair depilatory formulas and certain others, leading to aluminate (A102-) ion formation, plus hydrogen (H,) gas.
Since
aluminum is amphoteric, it should only be used with formulas having a pH of less than 12.0 at 25'C.
and then only when'reliably
lined.
If a generalized, non-pitting corrosion pattern is seen, it is best to use a lined or double-lined can.
Detinning is generally a 'good sign, showing
that the tin (not the iron) is anodic. should be changed.
0
If pitting is detected, the formula
Several options are described below:
Remove the offending or causative ingredient if possible, such as sodium lauryl sulfate. especially if chloride ion is present.
0
Add corrosion inhibitors, such as sodium nitrite, sodium benzoate, morpholine. or sodium silicates.
(Do not use nitrites in
conjunction with primary or secondary amines, or N-nitrosamines will very slowly form in sicu.
Many of these are carcinogenic.)
0.05% co 0.20% inhibitor is generally sufficient.
From
172
Alternative Formulations and Packaging to Reduce Use of CFCs
Increase the pH to about 7.6 to 8.8. if possible, by adding triethanolamine or curmonia (NH,OH Solution). Remove or minimize ionizing materials. i.e., those that permit electroconductivity and thus promote galvanic corrosion reactions Minimize chloride ion (especially).
It is a very active corrosion
promotor, even for underfilm corrosion.
It is critical to minimize
chloride ion when macerials such as sodium lauryl sulfate (which contains it in some grades) or lauryl polyoxyethylene sulfates are present. Sometimes specific corrosion inhibitors are required.
Sodium lauryl
sarkosinate and sodium coco-8-aminopropionate surfactants are useful for sodium iauryl sulfate. Coco-diethanolamide is good for nonionic surfactants. Virco-Pet 20 (composition proprietary, except that it is an organic phosphate), is good for dimethyl ether and water compositions. For some formulas, traces of moisture can be removed by using such scavengers as propylene oxide or epichlorohydrin.
(Very limited
evidence suggests that both may be mutagenic.) These chemicals are never recommended for cosmetics. Many formulations that are intensely corrosive to steel cans may be conveniently packaged in lined aluminum containers.
Examples are mousse
products and saline solutions. The latter contain 0.9% s o d i m chloride ( N a C l ) in water under nitrogen pressure.
3. Example Non-CFC Alternative Formulations COSMETICS. TOILETRIES. AND PERSONAL CARE PRODUCTS Hair Suravg In the U.S., hair spray (aerosol and pump-action) is the largest single category of the $3,000,000,000 hair care market. Aerosol hair spray is also the largest selling aerosol product.
In 1988, about 488,000,000units were
sold, at a retail value of about $1,150,000,000. The pump-spray alternative has several detractions, such as finger fatigue during use, longer application period, flexibility--andsometimes poor shape retention of the larger size containers and occasional plugging of the meterspray valve.
The formulations
must also be resistant to oxygen, since air is sucked back into the dispenser
with every actuation. The pump-action valve is rather costly, and this, combined with a generally smaller fill volume. has necessitated a fairly high price per unit of volume or weight.
Sales are relatively small, compared wich
the popular aerosol version. Both are normally anhydrous and flammable, although there are formulation options for substantially reducing the flarnmability of the aerosol product. Hair sprays are normally formulated with 1.3 to 3.0% of film-forming ingredients, commonly called polymers or resins. These materials tack dovn the hair after the product dries for a minute or
tvo,
preventing the displace-
ment of strands or curls by body motion or wind. On the other hand, plasticizers are included to ensure the flexibility of the entire hair mass, so that it can retain a healthy bounce and not feel too stiff.
A
feature of some
formulas is that extra stiffness can be imparted by spraying on more product,
if a more sculptured or rigid coiffure is desired.
173
Alternative Formulations and Packaging to Reduce Use of CFCs
174
The hair spray resin must have properties that include solubility in 95.5 vol% of anhydrous ethanol, a good feel on the hair, no stickiness or tackiness in moist atmospheres. lustrous (healthy) appearance, good holding power, good removability with shampoos, and sufficient flexibility to allow bounce and co resist junctura1 fracture.
To achieve the ideal property mix. nearly all film-forming resins are copolymers (dipolymers and terpolymers).
Of the seven or so used in the U.S.,
perhaps the most popular is Gantrex ES-225, made by the GAF Corporation. Chemically, it is the monoethyl ester of polyvinylmaleate/maleic anhydride copolymer, and it is normally purchased as a viscous solution of 50% solids in anhydrous ethanol.
For best results, the carboxylic acid moieties of che
polymer must be partially neutralized by the addition of certain amine compounds.
Another polymer, known as Gaffix, was introduced by the same
supplier in 1989 and is said to provide not only hair fixative properties but hair conditioning as well.
(The same quaternized material is recommended f o r
hai r mousses. ) The type and amount of resin and plasticizer (if needed) enables the final product to be sold as a Gentle Hold, Regular Hold, Extra Hold, Super Hold, or Ultimate Hold formulation. The differences between such products vary:
a Regular Hold by one marketer may have more holding power than an
Extra Hold by another.
In popularity, the Extra Hold and its equivalents have
a slight advantage, closely followed by the Regular.
While hair sprays
normally fall between the "price/value" (utility) and "luxury image" ends of the hair care market, many sell for several times the price of others.
The
"luxury image" products do not usually indicate their hair-holding ability, preferring to suggest that they are just right for all users. During the 1970s. many hair sprays were extended to provide supplementary benefits by the inclusion of such minor ingredients as Vitamin E (alpha tocopherol), silicones, myristyl myristate, aloe extract. elastin, and protein hydratolates.
The products of the 1980s still use many of these special
ingredients, but also claim to be "energizing," "volumizing," "revitalizing."
Example Non-CFC Alternative Formulations
"nourishing," "elasticizing," and good for "sun survival." matter,
SOM
175
Since hair is dead
of the claims refer to the scalp, not to the hair shaft.
The formulas in Table 6 illustrate vays of using both hydrocarbons and dimethyl ether as propellants.
The use of vater vith Gantrez and Resyn copolymers in hydrocarbonpropelled hair spray systems has been the subject of U.S. Patents held by the American Cyanamid Company.
Patents have also been issued covering the
inclusion of carbon dioxide as an additional propellant in dimethyl ether systems.
Both carbon dioxide and nitrous oxide are extraordinarily soluble in
dimethyl ether, dissolving at about 3.70% and 3.91%. respectively, for each one bar of pressure increase at 21'C. I n the U.S., the hydrocarbon hair sprays have generally been packed in lined tinplate or (sometimes) aluminum cans.
In other countries, plain
The dimethyl ether formulas are usually packed
tinplate cans are often used.
in plain tinplate cans or in aluminum cans with linings of PAM (polyamidimide) or special epon-phenolic types. The Precision Valve Corporation has developed effective valves for both hydrocarbon- and dimethyl ether-based hair sprays, using their well-knovn 2 X 0 . 5 0 m Aquas010 stem.
Other components include a 0.50 mm MBST (Mechanical
Break-up Straight Taper) button and butyl rubber stem gasket.
The very high
solvency effects of dimethyl ether require special gaskets for valves.
For
valve cups, cut gaskets of Butyl U105. Butyl U133, and Chlorobutyl CLB-82 (all by the American Gasket and Rubber Company) have performed vel1 commercially. The Precision Valve Corporation's Polyethylene-Sleeve gasket also gives good performance when used with tinplate cans, as do the polyethylene and ppolypropylene laminates. Since the drying time of alcohol is 2 9 times as quick as that of water, it may be surprising to know that the drying time of all four hair spray formulas is essentially the same. This is because the formation of
176
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 6. HAIR SPRAY FORHULATIONS USING BOTH HYDROCARBON AND DIMETHYL ETHER PBOPELIANTS (Regular Hold) ~
Ingredients Gantrex ES-225 (50% in Anhydrous ethanol) Resyn 28-2930 Amino-methyl-propanol (95%) N,N-Dimethyl-octadacylamine Dimethyl Phthalate D. C. Fluid 1193' Disodium Dodecylsulfosuccinate Sodium Benzoate Fragrance Deionized Water S . D . Alcohol 40-2 (Anhydrous) Propellant A-31 or A-40d Dimethyl Ether Pressure (532 mm Vacuum Crimp, 21'C) 21'C) Delivery Rate (g/sec 21'C) Flame Projection (mm 21'C) Flash Back to Button. (mm
-
-
Formula A
Formula B
4.00
4.00
_-__ __-_
0.09
0.29 0.03 0.02
_--_ ---_ ----
Formula C .
Formula 'D
_-__
.___
2.50 0.20
2.50 0.18
___-
0.03 0..04 0.20 0.08 0.15 16.00
_-___--
4 4 . ao
0.06 0.20 0.08 0.15 32.00 28.83
____
36.00
36.00
2.2 bar
2.5 bar
2.5 bar
3.7 bar
0.50 460 60
0.54 42s 50
0.60 250 0
0.65 225 0
___-
___-
0.10
----
67.56 28.00
__--
0.02
__-_
_--_ 0.10 8.79 61.00 26.00
----
----
--c
'Formulas C and D are based on information originally developed and published by Dr. Leonidus T. Bohnenn of Aerofako. BV. bvinylacetate/crotonic acid/vinyl neodecanoate copolymer, made by National Starch & Chemicals Corporation, U.S. (It can be replaced with Gantrez ES-225. but some detinning may occur at 3S'C or above.) 'A vater-soluble silicone copolymer, made by the Dow-Coming Corporation,
U.S.
dA-40 is an alternative propellant blend, consisting of 10% propane and 90X isobutane by veight. The pressures and other data for Formulas A and B are based o n A-31; 100% isobutane. *At full delivery rate. If the valve is throttled, the flashback of Formulas A and B will become 152 mm; i.e., to and touching the actuator.
Example Non-CFC Alternative Formulations
177
hydroalcoholic dimethyl ether azeotropes greatly accelerates the evaporation rate of water.
(This feature is useful in dimethyl ether formulations for
personal deodorants, paints, and several other aerosol products.) Until recently, methylene chloride, and, rarely, 1,l.l-trichloroethane were included in U.S. hydrocarbon hair sprays.
These solvents were removed in
between 1985 and 1988 because of the alleged carcinogenicity of these substances. Since the early 1950s. methylene chloride has been used in billions of cans of hair sprays.
It increases resin solvency, decreases flammability,
promotes evaporation rate, and causes the deposition of a smoother film with less junctura1 beading.
Concentrations of up to 25% have been tolerated by
both the dispenser and the consumer.
In greater amounts, however, the odor
and solvent effects become more significant.
For instance. plastic eyeglass
frames may glaze over time, and contact lenses may blush temporarily. A few individuals are sensitive to methylene chloride and may develop rashes or itching of the neck. Hair Lusterizerq Many people, but especially those Blacks, Hispanics, and others with very curly hair, have little need for standard hair sprays, but they often use hair conditioning and lusterizing sprays that convey the sheen and look of naturally healthy hair.
Some formulations for these products appear in Table 7.
Both hair sprays and hair lusterizers are sold in scented and unscented versions.
The "unscented" form actually has about 0.02 to 0.03% of a non-
descript floral fragrance in it to cover the slight chemical odors of the other ingredients. uses.
They are also sold for both consumer and professional end
The professional cans are often quite large (65 mm X 238 mm (666 mL
fill)l. and are generally of tinplate.
178
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 7.
HAIR CONDITIONER SPRAY FORMUIATIONS
Ingredients
Formula A
Formula B
Formula C
Formula
3.6
2.6
2.4
2.9
D
Isopropyl Hyristate' Mineral Oil; USP Isodecyl Oleate Volatile Silicone Fluidb Odorless Uineral Spirits PPC-lZ/PPG-50 Lanolins Pluriol 9400' Mink Oil Fragrance Deionized Water S.D. Alcohol 40-2 Anhydrou Iso-Butane (A-31) Propane/iso-butane (A-46) Dimethyl Ether Pressure (532 mm Vacuum Crimp) (bars, at 21'C) 'Cosmetic Grade.
May be replaced by isopropyl palmitate.
bAs Cyclomethicone F-251 (Dow-Corning Corporation). A blend of 25% Tetrameric Ring Compound and 75% Pentameric Ring Compound. The dimethylsilicone of 0.65 cstks. Viscosity may also be used. 'A propylene oxide
-
ethylene oxide surfactant polymer.
dSpecially Denatured ethanol. To make, add 400 g t.Butano1 and 45 g of Brucine Sulfate to 3.784 liters of ethanol.
179
Example Non-CFC Alternative Formulations
The mousse (French word for "foam") was first introduced in an aluminum can in the U.S. in 1973 as "Balsam and Body" foam.
The French-based firm of
L'Oreal, S.A., which researched this product type from 1975 to 1980, required a hair setting and conditioning foam that would leave the hair softer, more manageable, easier to brush, shiny, free of frazzles, having a good handle and slip, and with good body control and able to resist fly-away situations. The product was launched in Europe in 1981 and in the U.S. and Japan in 1983. 1988, world-wi&
In
sales were about 270,000,000 aluminum cans: about half of
this number was marketed in Europe. To achieve both hair set and conditioning characteristics, any one of three classifications of a specialty polymer must be used:
0
A combination of a slightly anionic "hair spray" film former, with a compatible cationic hair conditioning polymer:
0
A cationic conditioning polymer that can also function as a hairsetting agent: or
a
An amphoteric hair-setting and conditioning polymer, sometimes augmented by the addition of quaternary conditioning ingredients.
One of the more popular compounds is Cafquat 7551 (20% dispersion in water), which is a quaternary ammonium polymer formed from dimethyl sulfate and a copolymer of vinyl pyrrolidone and dimethylaminoethyl methacrylate.
The
second approach is to use a two-component system, such as a combination of GAF Corporation's Copolymer 845 (20% in water) poly(vinylpyrrolidone/dimethylaminoethyl methacrylate, for hair setting plus a quaternary, such as CibaGeigy's Bina Quat 44C:
hydroxyl-cecylammonium phosphate.
Supporters of the
two-component system claim they can adjust the degree of set and degree of conditioning independently, to conform to perceived marketing requirements.
A
large number of other products are available, but the anionic and cationic moieties have to be selected for compatibility or precipitation may occur.
A
Alternative Formulations and Packaging to Reduce Use of CFCs
180
well-quaternized resin will exhaust substantively onto the towel-dried hair when the product is worked into it following shampooing.
In a typical case,
about 175 mg per 100 g of hair will exhaust from dispersions of 0.3% concentrations or higher in the product itself.
This 0.1752 level is all at the
hair ourfacm. and provides such properties as silkiness, shine, volume, handle, lack of fly-away, lubricity, manageability., and anti-static properties.
It also avoids any sense of limpness or buildup on the treated hair.
After the hair set and conditioning agents are chosen, an emulsifier must be selected. A minimum amount should be employed, so the user can apply the mousse without needing to rinse the excess out of the treated hair.
This is
especially important in the case of emulsifiers, where the excess can turn the hair slightly waxy, sticky, and dull.
Some common selections include oleyl
diethanolamide, ethoxylated (9 mol) octylphenol, polyethylene glycol (10 mol) ether of stearyl alcohol, mixed monooleate esters of sorbitol and sorbitan anhydride with an average of 20 moles of added ethylene oxide (Polysorbate 80) and polyethylene glycol (20 mol) ether of stearyl alcohol (Brij 720 or PEG-20 Stearate).
In general, the most effective are nonionic ones at levels of 0.3
to 0.7%. The emulsifier must ensure good dispersion of the propellant, good foam formation. and some initial instability of the foam when applied. must quickly collapse when rubbed onto the wet hair.
It
Good wet and dry
combing, foam wetting, moisture retention, and emmolliency are generally conveyed by the use of these ethoxylates and propoxylates. Like the hair sprays and lusterizers, mousse products often contain a host of specialty ingredients at levels often ranging from 0.001 to 0.100%. These include aloe vera extract, jojoba oil. chamomile extract, protein derivatives, elastin, allantoin, other quaternaries, birch (tree) extract, marigold (flower) extract, walnut leaves (tree) extract, and various sunscreening agents.
They may or may not convey any real benefit, depending on
the concentration used in the formula.
Some mousse products also contain
colorants or dyes, of which perhaps the most common is FDdC Yellow 67 (in the U . S . ) . used at 0.002 to 0.008%. All mousses are perfumed.
Example Non-CFC Alternative Formulations
181
Bacterial proliferation can occur in some mousse formulas. so they are often protected with 0.10% methyl p.hydroxybenzoate and 0.05% n.propyl --
p.hydroxybenzoate.
Other, more powerful and broader spectrum preservatives
are now being favored, such as Kathon CG ( R o b 6 H a a s Company) and Dowicil 200
(Dov Chemical Company).
In general, the finished mousse concentrate or
aorosol should be able to pass a microbial Total Plate Count test with a reading of "less than 10 organisms per I&."
It is also recommended that the
tank, hoses, pumps. filters, and filler bowls be sanitized and that the
deionized water used in batchmaking be first heated to 70'C
to kill pseudo-
monads and most other microorganisms. The usual propellant for mousse products ia A-46 (15 weight % propane, in 85 weight % isobutane), which develops mousse pressures in the area of 4 . 0 bar
at 21.2.C. 15I.
The usual amount is 6.5 to 7.5%. but some products use as much as
For some specialty products, such as mousse used on babies, absolutely
no evidence of flammability can be tolerated.
With the straight hydrocarbon
formulas, touching a lit match or lighter to the surface of the foam will produce a momentary ignition.
This can be eliminated by using a propellant
blend that includes 30% or more HFC-152a. The A - 4 6 and HFC-152a can be purchased as a blend, premixed by those fillers who have blending stations, or added consecutively using two separate gassing machines.
Because the HFC-152a
is only present in concentrations of 2% or so, the cost penalty is relatively low. The general considerations involved in formulating a mousse hair set and conditioning product have been described, and some illustrative formulations will now be presented.
Table 8 describes four formulations fully, giving
first the U.S. Cosmetic Ineredients Dictionary (CTFA-CID) terminology, followed by the chemical name, brandname(s). and source.
Table 9 describes
four additional formulations in a format of decreasing order of ingredient concentration (except that ingredients whose concentrations are less than 1% may be placed in any order), in accordance with U.S. Food and Drug Administration (FDA) regulations. These regulations require ingredients of food, drugs,
182
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE a.
UOUSSE HAIR
sm
AND CONDITIONING PRODUCT FORMULATIONS % (w/wl
Polyquaterniun 4 Copolymer of hydroxy-mthylcellulose and diallyl-dimethyl ammonium chloride
Soft Set
Firm Sec
0.60
1.00
75.85
75.25
0.15
0.20
0.10
0.15
0.15
0.30
0.15
0.10
14.90
14.88
0.10
0.12
Celquat L-200 (100% A.I.) by National Starch & Chemical Corporation Deionized Water Dimethacone Dimethyl silicone derivative emulsion DC Silicone Emulsion by Dow-Corning Corp. Tallow Trimonium chloride (and) isopropanol stearyl/palmityl trimethyl ammonium chlorides; 7 5 X , in isopropanol Arquad T-50 (75% Active Ingredient) by the Industrial Chemicals Division of Armak Corp. Octoxynol 9 Ethoxylated (9) n.Octylpheno1 Triton X-100, by the Rohn 6 Haas Corp. Emulsifying Wax NF Fatty alcohol derivative
-
Self emulsifying
Polawax A-310. by Croda, Inc. Polawax A-310. (100% A.I.) by Croda. Inc. Ethanol SD40 Ethanol (Denatured #40; 100%) S.D. Alcohol 40; anhydrous, by U.S. Industrial Chemicals Division Perfume Oil (Floral) Continued
Example Non-CFC Alternative Formulations
TABLE 8.
(Continued)
X (w/wl
J
8.00
Propellant A-16 15 vt. X propane & 85 vt.X isobutane
8.00
A 4 6 Propellant by Phillips Petroleum Go.;
Specialty Products Division Fo-a
B
S
Quaternium 11 Poly (vinylpyrrolidone/dimethylaminoethyl methacrylate)
x (w/wl 7.00
Copolymer 81r5 (20% Solids in Water) by GAF Corp. Polyquaternium 16 Hydroxyethyl cetyldimoniun phosphate (100% A.I.)
3.50
Bind-Quat U C (100% A.I.) by Ciba-Ceigy Corp. Cocoamid DEA Coconut acids diethanolamine condensate (1:l) (Free of soap and anide esters) (Superamide) Standamid SD (100% A.I.) (Henkel Chemical Co.)
1.00
Tallow Alkomium Chloride Dimethyl benzyl tallow ammonium chloride
0.50
Incroquat S85 or SDQ-25 (Croda, I C . ) Deionized Water Methylparaben Methyl p.hydroxybenzoate
77.65 0.08
Nipagin M (Nipa Laboratories. Ltd.) Perfume Oil (Floral)
0.26
FDG or DM (Color)
0.01
Propellant A-46 16 ut X propane & 84 ut X isobutane
A-46 Propellant by Phillips Petroleum Co.; Specialty Products Division Continued
183
10.00
184
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 8.
(Continued) C
x
nts Polyquaternium 11 A quaternary ammonium polymer formed by the action of dimethyl sulfate on a copolymer of vinylpyrrolidone and dimethyl amino ethyl methacrylate. Gafquat 734, (50% A . I .
(w/wl
1.32
in Ethanol), by the GAF Corp.
Polyquaterium 4 A copolymer of hydroxymethylcellulose and diallyldimethyl ammonium chloride.
1.00
Celquat H60 (100% A.I.) by National Starch and Chemical Corp Silicone Silicone polymer. end-blocked with aminofunctional groups
0.15
Cationic Emulsion 929 Dow-Corning Corporation Oleamidpropyl Dimethylamine Hydrolysed Animal Protein Oleylamidopropyl diethylamine hydrolysed animal protein.
0.20
Lexein CP-125. by the Inolex Corp. Potassium Coco-hydrolysed Animal Protein Animal protein hydrolysed in boiling potassium cocoate soap solution..
0.14
Lexein S620, by the Inolex C o w . Aloe vera Aloe vera
0.05
Aloe Vera: Pure Extract (90% A.I. Powder), Terry Chemical Company PEG 150 Hydro-(erhyleneoxide 150) alcohol
0.26
Carbowax 8000, by Union Carbide Corp. or Polyethylene Glycol 6000 by Dow Chemical Company Quatermium 52 Dibutyl sebacate Dehyquart SP. by Henkel Chemical Company Continued
0.20
Example Non-CFC Alternative Formulations
TABLE 8. (Continued)
x
edients Ethanol SWO Ethanol (specially denatured #40; 100%)
(v/vl
3.00
S.D. Alcohol 40; Anhydrous, by Shell Chemical Co. Polysorbate 20 Kainly the monolaurete ester of sorbitol and sorbic01 anhydrides, condensed with 20 moles of ethylene oxide.
0.05
Tveen 20 by I C 1 Americas, Inc.. or Nikkol TLlO or TLlO-EX by the Nikko Chemical Company Fragrance (Floral)
0.209
FDhc or D6C (Color)
0.001 85.42
Deionized Water Propellant BIP-55 Ethane Propane Iso-butane n.Butane Pentanes Hexanes Unsaturated Hydrocarbons Sulfur compounds Warer
8.00
0.290 w.X 30.728 26.509 39.759 2.700 0.010 0.001 maximum 0.0005 maximum 0.0025 maximum
Propellant IBP-55 by Phillips Petroleum Company. Specialty Products Division. Formula D Ineredients Polyquaternium 11 Quaternary ammonium polymer of dimethyl sulfate and the copolymer of vinylpyrrolidone and dimethylaminoethyl methacrylate. Qafquat 7551 (20% in water), by GAF Corp.
% (v/v)
5.00
185
186
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 8.
a D
-~
PVP Polyvinylpyrrolidone (Nol. wt.
(Continued)
-
1.00 30,000)
W P (K-30) (GAF COW.) Carbomer 941 Polymer of acrylic acid, cross-linked with a polyfunctional agent
15.00
Carbopol 941 (Use as 2.02 in Water) B.F. Goodrich 6 Co 0.28
Ammonia Ammonium Hydroxib (29% in Water)
-
Steardimonium Hydrolysed Animal Protein Purified. Stearyl dimethyl -onium modified hydrolysed protein
0.28
Croquac SP (Croda, Inc.) Nonoxynol-20 Ethoxylated (20) n.nonylpheno1
0.28
Igepal CO-850 (GAF Corp) Steareth-2 Polyethylene glycol (2) ether of stearyl alcohol CH,(CHz) &+~(OCHZCH~)ZOH Brij 72 (IC1 Americas, Inc.)
0.28
Polysorbate 20 ktainly the monolaurate ester of sorbitol and sorbitol anhydride, condensed with an average of 20 moles of ethylene oxide.
0.50
Nikkol 73.10 or 73.10-EX (Nikko Chemical Co.)
Hethylchloroisolthiaolinone and ktethylisothiazolinone Iathon CG ( R o b 6 Haas Company) Fragrance Deionized Water Continued
0.24 68.00
Example Non-CFC Alternative Formulations
TABLE 8.
(Continued)
ts
Hydrofluorocarbon 1 5 U 1.1-Difluorethane
x
(v/vl
6.40
-1-152 ( E . I . W o n t & Nemours h Co., Inc.) Genotron-152a (Allied-Signal Corporation) Isobutane Isobutane A - 3 1 (Phillips Petroleum Co.) Aeron A-31 (Diversified Chemicals and Propellanrs Go.)
2.74
187
188
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 9.
INGREDIENT LISTINGS OF OTHER MOUSSE HAIR SETS
AND CONDITIONERS.
With Sunscreen Water Hydrofluorocarbon 152A Isobutane *Polyquaternium-11 *DEA-Methoxycinnamate Polyquaternium-4 Dimethacone Copolyol Fragrance *Isosteareth-10 Sodium Cocoyl Isethionate Methyl Paraben *Lauramide DEA *DMDM Hydantoin
3 . DO-GU) XYZ
Co.
-
Alc oho 1 Fr ea S tY
Housses
A 230-gram fill in aluminum can H ’ Water Isobutane PVP/Dirnethylaminoethyl methacrylate copolymer Polyquatermium 4 *Diphenyl-dimechicone *Lauramine Oxide DHDM Hydantoin Fragrance *Quarernium 18 Butane *Ammonium Laureth Sulfate *Disodium Ethylenediamine Tetraacetate (EDTA) Citric Acid Continued
Example Non-CFC Alternative Formulations
TABLE 9. (Continued)
3.
Do -GLO XYZ
CO.
Alcohol-Free S t v u Mou s e s A 230-gram fill in aluminum can U t r a Bodv
-
for Fine Ha&
Water Isobutane Polyquatermium 4 Propane *Lauramine Oxide Propylene Glycol Wctyl Salicylate Panthenol *Silk Amino acids *Keratin Amino acids *Hydrolysed Animal Keratin Butane Citric Acid DMDM Hydantoin Fragrance *Disodium Ethylenediamine Tetraacetate (EDTA) 4.
DO-GLO XYZ
CO.
A 1cohol-Free Stvline Mousses
A 230-gram fill in aluminum can Moisture Rich
-
for Dry or Damaeed Hair
Water Propane Isobutane *Acetamide Monoethylamide (MEA) PVP/Dimethylaminoethylmethacrylate Copolymer Butane Cocamide Diethanolamide (Superamide) Panthenol (N-Pantothenylamindoethyl)disulfide *Glycereth-26 *PEG-150 Distearate Sodium Lactate *Sodium PCA Co 1lagen
189
190
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 9 .
(Continued)
'All ingredients are listed in decreasing percentages, except for those present in concentrations of less than 1.0 percent. *These ingredient designations are identified chemically in the following way: Acetamide MEA: Acetamide Monoethylamide Lipamide MEAA (Lipo Chemicals, Inc.) Ammonium Laureth Sulfate: Ammonium salt of ethoxylated (1-4)lauryl Sulfate Carsonol ALES-4 (Lonza Chemical Corp.) DEA-Methoxycinnamate: Diethylaminomethoxycinnamate ( S u n Screen Agent) Diphenyl-trimethicone: Silicone 556 Fluid (Dow-Corning Corporation) Disodium EDTA: Disodium Ethylenediaminetetraacetate DHDM Hydantoin: 1,3-Dimethylol-5.5-Dimethyl Hydratoin Glycereth-26: Polyethylene Glycol (26) Glyceryl Ether Ethosperse G - 2 6 (Glyco Chemical Company) Hydrolysed Animal Keratin: Keratin, hydrolysed Isostreareth-10: Polyethylene Glycol (10) Ether of Isostearyl Alcohol Keratin: Keratin Amino Acids Kerapro (Hormel Company) Lauramide DEA: Lauric Acid - Di-ethanolanide (1:l) Condensate Superamide Lauramine Oxide: n.Laury1-dimethylamineoxide Octyl Salicylate: 2-Ethylhexyl Salicylate C,,H,,O, (Sunarome WMO-Felton) PEG-150 Distearate: Polyethylene Glycol (150 mol) Distearate Lipopeg 6000-DS (Lipo Chemicals. Inc.) Polyquaternium 11: A quaternary ammonium polymer formed from dimethyl sulfate and a copolymer of vinylpyrrolidone and dimethyl amino ethyl methacrylate. Quaternium 18: De(hydrogenated tallow) Dimethylammonium Chloride Adogen 442 (Sherex Corporation) Silk Amino Acids: Amino Acid Blend, derived from Silk Protein (Croda. Inc.) Sodium PCA: Nalidone (UCIB) U . S . Distributor: S.S.T. Corporation (Clifton, NJ)
Example Non-CFC Alternative Formulations
191
and cosmetics to be listed on the product label in this fashion, unless they are for professional or institutional use. rs for Hair Set-
and C o n d i t f o n i n P .
Mousse formulas are norrnolly finished to a pH value of approximately 5 . 5 to 6.5 at 25'C.
They are either aqueous or hydroalcoholic and contain
surfactant wetting agents and a high concentration of chloride ion, a well-
known corrosion promoting agent.
It is not surprising that they are corrosive
to steel and tinplated cans and may even attack aluminum cans unless they are vel1 lined.
Many mousse formulations contain corrosion inhibitors, such as
sodium benzoate, coco-diethanolamide, and amino groups to provide additional shelf-life stability. During 1984 and 1985. a large amount of work went into developing welllined tinplate cans for mousse formulas to take advantage of the much lower prices of tinplate.
In 1984, one major marketer introduced a low-priced
mousse in a 45-~pm diameter tinplate (necked-in) can.
Special techniques were
used to make the formula less aggressive, and the can was heavily double-lined vith an Organosol hydridized vinyl coating system. well on the market.
The product is still doing
The only other mousse products in tinplate cans are lines
of large, salon-type mousse products sold to a number of marketers by one formulating house. length.
The cans are 52 rrrm in diameter by approximately 190 nun in
They have necked-in construction.
They are made only by the Conti-
nental Can Unit of the United States Can Company and, uniquely, use a third body lining (after welding and flanging) as a repair coat, to cover up any abrasions or scratches made during manufacture. product.
These cans contain 298 g of
A developmental can of polypropylene-laminated tinplate or tin-free
steel is performing well virh mousse products after a year of storage. Aluminum cans for mousse applications are typically 38. G5. or 52 nun in diameter and are up to 165 mm long. All are of one-piece construction and are heavily single or double lined. The usual epon-phenolic linings for aluminum cans are sometimes inadequate for mousse products and have generally been replaced vith linings made of pigmented epoxy-phenolics, PAM clear polyamid-
192
Alternative Formulations and Packaging to Reduce Use of CFCs
imide, and the popular Micoflex L6X392 beige-pigmented vinyl Organosol.
In
some cases, two separate linings of the same material are applied. Nearly a11 valves for mousse hair care products use aluminum mounting cups coated on the outside and lined on the inside surfaces.
Numerous
problems have arisen from trying to make a good seal, especially in the case of the larger-diameter 52- and 66-mm cans,
Bonded polyethylene sleeve gaskets
(an exclusive development of the Precision Valve Corporation) are satisfactory if the new Rfng Seal mounting cup contour is used. as are the full-coverage polyethylene laminate gaskets--again, if a special contour valve cup is used. These gaskets require a special mousse-resistant adhesive if continuing attachment to the inner surface of the valve cup is a marketer requirement. Otherwise, the laminate will separate eventually and droop slightly.
Some
technical experts are concerned about the possible corrosivity of concentration cells that can be created between the laminate and unprotected aluminum cup. Any liquids that may accumulate there must enter by permeating the polyethylene: therefore, unknown compositions and concentrations may form. Also, the adhesive is generally an excellent barrier material, but this advantage is lost if delamination occurs. Full
Most hair care mousse products are designed to be vertical acting. coverage of the mounting cup is an aesthetic benefit.
The "pad-and-smokes-
tack" type is popular, as is the tilt-action, simple "smokestack" design. Foam spouts are either white or the color of the base coat of the can.
The
protective cover will either fit over the spout or valve cup outside diametrer. or be designed to have the same diameter as the can. for a cylindrical look. Many U.S. marketers are testing the Fibrenyle Ltd. "Petasol" or PET (polyethylene terephthalate) plastic bottles for mousse applications, with good results.
One problem that must be resolved is that the U.S. Department
of Transportation (DOT) will not permit interstate shipments of non-metallic
aerosol containers if cheir capacity exceeds 118.3 mL because of a regulation that dates back to 1951, when the only non-metallic aerosol containers were those made
of
glass.
Special exemptions based on impressive arrays of test
Example Non-CFC Alternative Formulations
data. including drop test results, have now been requested.
193
Meanwhile,
several nev bottle shapes are being developed. gther Mousse Product+ The original hair setting and conditioning mousse products of 1981 and later have made it possible for marketers to successfully introduce an impressive number of related foam products. Several still involve various aspects of hair care, such as hair sheens or lusterizers. hair depilatories, dandruff control foams (using zinc pyrithrone or an alternative dandricide). hair coloring mousses. and mousse products to help control ear itch and "jock itch," a trichophyta1 fungal mycosis of the pubic area related to the wellknown "Athlete's Foot" problem.
Other hair care products include baby oil
formulas. baby shampoos, curl activators, and products that promise a hair thickening effect.
A hair restorative material is now being sold in mousse
form. The remaining second-generation mousse products are generally for skin care.
They include make-up items, baby oil formulas (again). sunscreens,
facial cleansing foams, hand creams, skin smoothing (20% talc) products, cationic skin emollients, dewrinkler formulas, etc.
Mousse products can be
used to contain and deposit large amounts of specialty oils on the skin, such as a product that contains 25% jojoba oil (Wickenol 139. Dow-Corning Corp.), which claims to give the skin a healthy sheen and superior lubricity. The specialty "mousse gels" consist of lines of products that deliver as clear or translucent gels but spring into mousse foams on contact with che hand.
Table 10 presents several formulations illustrating these newer
products. The mousse packaging system is an ideal vehicle for dispensing sunscreens and suntan lotions as foams that quickly break up on mechanical shearing to produce exceptionally even matte finish results.
The first to introduce this
product was Schering-Plough. Inc. as one of several package forms for Coppertone. More recently, in 1984. the Golden Sun Company introduced their Sun Goddess Body Mousse Protective Sun Tan products in a 170-g filling weight.
194
Alternative Formulations and Packaging to Reduce Use of CFCs
-
TABLE 10. SPECIAL= MOUSSE FORPIOZATIONS
x
(w/wl
Stearimidopropyl Cetaryl Cfoonium Tosylate (and) Propylene Glycol. (Ceraphyl 8 5 . by Van Dyk C Co., Inc.)
0.50
Quaternium 26 (Ceraphyl 65, by Van Dyk 6 Co., Inc.)
0.75 20.00
C9-11 Isoparaffins (99+% C,-CI1 Branched Paraffinics) Isopar K. by W o n , Inc. Isodecyl Oleate
4.00
C12-15 Alcohols Benzoate
1.00
Fragrance
0.25
Deionized Water
68.50
Isobutane A-31 (Aeropres Corp.) (Propellant A-66)
4.25
Propane A-108 (Aeropres Corp.) (Propellant A-46)
0.75
Note:
The foam may be destabilized by adding 0.5% of a volatile silicone such as CTFA Cyclomethicone, alcohol, or by replacing part or all of the hydrocarbon propellant (A-46) with hydrofluorocarbon 152 (CH, Stability can be increased by adding cetyl alcohol. CHF,).
Babv Shamo00 and ConditioneK Ineredients
x
(V/Wl
Sodium Laureth (3) Sulfate [Sodium Lauryl (3 ETO) Sulfate]
40.00
Cocoamidopropyl Betaine (Cocoamidopropyl dimethylglycine) Aerosol 30 by American Cyanamid Company, or Velvetex BA-35 by the Henkel Chemical Company.
16.00
Benzyl Alcohol Continued
0.25
Example Non-CFC Alternative Formulations
TABLE 10.
(Continued)
tS
%
(w/wl 0.25
Methyl p.Hydroxybenzoate PEG-150 [H-(OCH, -CH,),,,OH] Chemical Company.
0.25
Carbovax 8000 by Dov
0.25
Fragrance
37.00
Doionized Water Isobutane A-31 (Aeropres Corporation) (Propellant A-46)
5.10
Propane A-108 (Aeropres Corporation) (Propellant A-46)
0.90
Note:
The first two ingredients may be replaced with 34.00% Disodium Oleanido PEG-2 Sulfosuccinate. 20.00% Sodium Laureth (3) Sulfate, and 2.00% Quaternium 22 substantive conditioner and humectant. The last item io available as Ceraphyl 60 from Van Dyk 6 Company, I n c .
U v - SDread-atiVe
Kousse
Innredienrs
% (w/wl
Ethyl Ester of PVH/HA Copolymer (Gantrez ES-225, by the GAF Corporation; 50% A.I. in Ethanol)
5.00
Dimethicone Polyol (Surfactant 193 Fluid, by Dow-Corning Corporation)
0.50
Amino methyl propanol (95%) min.) AMP-95. by the IMC Corp.
0.20
Fragrance
0.20
Ethanol (Anhydrous Basis) S.D. Alcohol 40 (ZOO'), by Publicker Industries, Inc.
10.00
Deionized Water
75.10
Lsobutane A-31 (Technical Petroleum Company) Continued
195
7.65
196 Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 10.
(Continued)
F o d a G (Corlfiayad)
u.x&l
S
Propane A-108 (Technical Petroleum Company) Note:
1.35
The water-soluble 193 Surfactant acts to plasticize the copolymer and to enhance the spreadability of the resin on the hair. It also enhances foam building and foam stability. The possible need for a preservative should be investigated. although most of these formulas do not need one.
H Blcohol-Free Mousse for Damaned Hair b-dients
% (w/wl
Polyquaternium 11 (Cafquat 7553 by GAF Corp.)
7.50
Blend of Trimethylsilylamodimeticone. Octoxynol 40, Isolaureth-6 and a glycol. (Dow-Corning 42-7224: Dow-Corning Corporation)
1.00
Oleth-20 (PEG 20 Ether of Lauryl Alcohol) (Brij 98, by IC1 Americas, Inc.)
0.50
Fragrance
0.20
Deionized Water
81.80
Isobutane A-31 (Technical Petroleum Company) (Propellant A - 4 6 )
7.65
Propane A - 1 0 8 (Technical Petroleum Company) (Propellant A - 4 6 )
1.35
Note:
The Dow-Corning Q2-7224 conditioning agent provides improved wet and dry combing and imparts a good handle or feel to the hair. The agent is particularly effective on damaged hair. Combinations of about 3.0% Polyquaternium 11. 0.3% Polyquaternium 10, 0.3% Steareth 10 (Brij 76) and 0.15% PEG-2 Oleammonium Chloride A r m a k ) form a good base for alternative formulas. (Ethoquad 0/12 In some cases. up to 6.0% ethanol may be added.
-
Continued
Example Non-CFC Alternative Formulations
TABLE 10.
(Continued)
x
Jn-dients
(w/wl
32.00
Propylene Glycol Isodecyl Oleate or Hyristyl blyristate
4.00
C12-Cl5 Alcohols Lactate Ceraphyl 41 by Van Dyk 6 Co., Inc.
6.00
Glycerine
5.00
Quaterniun-26 (Hydroxyethyl) Dimethyl (3-Mink animal oil amidopropyl) Chlorides. Ceraphyl 65 by Van Dylc 6 Co., Inc
2.00
Quaterniun-22 3-(D-Gluconoyl-amino)-N-(2-hydroxyethyl)N.N-Dimethyl-1-propanaminiun Chloride. Ceraphyl 60 by Van Dyk 6 Co., Inc.
1.50
Dimethacone Polyol PEG-40 Stearate Stearic Acid
Silicone Fluid L-720 by Union Carbide Corp.
Polyethylene Glycol ( 4 0 mol) Mono-ester of
1.50 1.50
Cetyl Alcohol
0.50
Fragrance
0.25
Methyl p.Hydroxybenzoate
Nipagin M by Nipa Laboratories, Ltd.
Deionized Water
0.25 40.50
Isobutane A-31 Phillips Petroleum Company (Propellant A-46)
0.75
Propane A-108 Phillips Petroleum Company (Propellant A-46)
4.25
Note:
197
The propylene glycol and glycerine are hair curl activators, while the Isodecyl Oleate and C12-Cl5 Alcohols Lactate are glossing agents. The Quaternium 22 is an optional agent, used to increase humectancy and conditioning.
198
Alternative Formulations and Packaging to Reduce Use of CFCs
Four products were presented, with SPFs (Sun Protection Factors) of 2, 4 , 6 , and 12.
For example, a product with an SPF of 12 will enable the user to
remain in the sun twelve times as long as the standard period required to develop slight redness, while developing the same degree of coloration. Since 1984, a number of relatively low-sales-volume sun screen mousse formulas have been launched.
Some are identified as "sun screens;" others are
labeled "sun and sport styling mousses" or other. less definitive names. Table 11 lists the ingredients of two strengths of typical sunscreen mousses. Sun protection formulations with SPF values of 15 to 20 (the practical maximum) are often called sun-blocks (see Formula J in Table 11).
They
require combinations of sun-screen agents of the oil- and water-soluble type, to get the best distribution on the skin. using buffering agents, is required.
In some cases, rigorous pH control,
Concentrations of from 5.5 to 10.0% are
required, depending on the efficiency of the screening agents, type of mousse emulsion, distribution on the skin, repeat applications, skin condition and moisture content, individual sensitivity, skin color, season, time of day, elevation, geographic latitude, type of activities, perspiration rate, product application thickness. etc. For most people, a lesser degree of protection is acceptable.
For those
spending tvo or three hours in the sun at one time. the use of products with an SPF of about 4 to 6 is satisfactory. These products also permit the development of a tan, which is often socially important to those people or races having light-colored skin pigmentation. Formula K. shown in Table 11, provides this intermediate degree of sun protection, based on the use of iso-amyl-p-methoxy-cinnamate. This waterinsoluble material provides SPFs of 4 (at 2 . 8 % ) . 6 (at 3 . 6 % ) , 8 (at 4.5%), and 12 (at 7.5%).
Thus, the formula can be adjusted to give whatever degree of
solar protection is desired.
Example Non-CFC Alternative Formulations
TABLE 11.
SUNSCREEN MOUSSE FORHULATIONS
usse (SPF &out
151 UJLGCl
Isodecyl Oleate or Pfyristyl Nyristate Isodacyl Oleate is available from Van Dyk & Co., Inc. as Ceraphyl 140-A.
6.00
Octyl Dimethyl PABA (formerly Padamate 2) Ester of 2-Ethylhexyl Alcohol 6 Dimethyl p.aminobenzoic Acid
6.85
Escalol 507 by Van Dyk & Co.. Inc.
-
Benzophenone 3 2-Hydroxy-4-methoxybenzophenone
3.20
Uvinol M40 by BASF-Wyandotte Chemical Company Stearic Acid Octadeconoic Acid
10.00
Cetyl Alcohol Hexadecyl Alcohol
0.45
Deionized Water
44.95
Hydroxypropyl Methylcellulose Methocel F. by Dov Chemical Company, or Viscontran MHPC by Henkel Chemical Company
0.55
Propylene Glycol
2.50
Triethanolamine 99Z Triethanolamine by Union Carbide Corp.
1.15
Ethanol Alcohol (Anhydrous Basis; Specially Denatured) S.D. Alcohol 40 by U.S. Industrial Chemicals Division Continued
18.00
199
200 Alternative Formulations and Packaging to Reduce Use of CFCs
T A B U 11.
(Continued)
x
tS
TEA Coco-Hydrolysed Animal Protein (and) Sorbitol Triethanolamine Salt of the condensation product of coconut acids and hydrolysed animal protein
(w/w)
1.00
U p o n 4CT by Stepan Chemical Company Methyl p.Hydroxybenzoic Acid
0.1s
Perfume
0.20
Isobutane
4.25
Propane
0.75
Sunscreen Mousse (SPF About 6 1 ts Steareth-10 PEG Ether of Stearyl Alcohol; CH3(CH2),,CH,(OCHzCHz)l@H
x (w/wl 0.80
Brij 76, by IC1 Americas, Inc. PEG 150 Distearate Polyethylene Glycol (150) Diester of Stearic Acid
0.60
Kessco X-211 by Armak Chemical Company, or Witconol L.32-45 by Witco Organics Division. Sodium Hyaluronate Sodium hyaluronate - high-molecular-weight polymer from animal protein (90% powder) by Tri-K Induscries, Inc. (Reseller for Canadian Packers, Ltd.)
0.10
DMDM Hydantoin 1.3-DimethyloI-5.5-Dimethyl Hydantoin
1.10
Dantoin DMDMH-55 (or Glydant) by Glyco Products, Inc. Continued
Example Non-CFC Alternative Formulations
TABLE 11.
(Continued)
x (w/wl
nts
8.50
Quaternfum 52 Dibucyl Sebacate Dehyquart SP, by Henkel Chemical Co. Isoamyl Methoxycinnamate (CTFA) (FDA is pending) I s o a m y l - p - n a t h o x y c i n t e (98% min.)
3.60
Neo-Heliopan El000 by Haarmam 6 Reimer Japan K.K. Cyc lomechicone Cyclic dimethylpoly (3
-
2.50 4) siloxane
Silicone /I344 Fluid by Dov-Corning Corporation Dimethacone Copolyol (Water Soluble) Dimethylsiloxane, end-blocked with surfactant groups
0.25
Silicone 1193 Surfactant by Dow-Corning Corporation Polysorbate 80 Mixed oleate esters of sorbitol and sorbitol anhydride; mostly the monoesters, with 20 moles of ethylene oxide
0.15
Tween 80 by IC1 Americas, Inc Polysorbate 20 Mixed laurate esters of sorbitol and sorbitol anhydride; mainly the monoesters, condensed with about 30 moles of ethylene oxide.
O.GO
Nikko TLlO or TL-1OEX by Nikko Chemicals, Lrd. or Tween 20 by IC1 Americas, Inc. Olealkoniun Chloride Oleyl-dimethyl-benzyl-ammonium Chloride Ammonyx KP by the Onyx Unit of Stepan Chemical Co. Continued
0.10
201
202 Alternative Formulationsand Packaging to Reduce Use of CFCs
TABLE 11.
(Continued)
0.10
N o n ~ ~ y n o20 l-
Ethoxylated (20)-p-n.nonylphenol Igepal CO-850 by GAF Corporation, or Tergitol NPX by Union Carbidm Corporation Aloe Vera Aloe Vera Extract
-
0.10
100% Pura (90% A.I. Powder)
Aloe Vera 100% by the Terry Corporation Perfume
0.30
!!ethylchlorisothiarolinone, and Hethylisothiarolinone Kathon CG by R o b & Haas Company
0.10
Hydrofluorocarbon 152 1.1-Difluoroethane
4.00
Dymel 152 by E.I. DuPont de Nenours 6 Company, Inc. Isobutane Isobutane A-31 by Phillips Petroleum Company
2.00
Example Non-CFC Alternative Formulations 203
The mousse presentation can also be used for baby care products. They
avoid the spillage and application problems of other formulations. Table 12 lists the ingredients of these formulations. Other comercial mousse products include a facial cleansing preparation based on very mild surfactants such as disodium cocoamido MIPA sulfosuccinate
and sodium laureth sulfate, including Quaternium-22 to provide conditioning and emolliency. A facial makeup mousse uses a triethanolamine stearate and PEG-20 stearate emulsifier combination to spread a combination of pigments and emollients on the face to give an elegant matte finish. Hand creams are also available, again based on triethanolamine stearate and PEG fatty acid condensates as the emulsifier. Glycerin ( 5 % ) is included as a humectant. More recently, a cationic skin mousse has appeared that includes mink (animal) amidopropyl dimethylamine to provide a unique lubricity and skin feel. Several more interesting products are under intensive development. The vaginal contraceptive foam is a product in the drug category that depends on foam stability and density. The preferred active ingredient is Nonoxynol 9. or nonyl-phenoxypolyoxyethyleneethanol. The formula for a mousse product of this type has been published, and a variation is presented as
Formula N in Table 13. Commercial formulas in the U.S. range from 8-12.51.of Nonoxynol 9 . and
a l l the aerosols are pressurized with about 8% of a blend of CFC-12 and CFC-
114. A n Amended New Drug Application (to the FDA) will be required before the propellant can be changed to hydrocarbon or other types. This process takes the FDA about 3 to 5 years to complete, since the entire NDA file must be reviewed whenever a change is made. A mousse product is also available for the treatment of mastitis infections in the udder of cows. An example is presented in Table 14. A
similar formula, based on the use of Procaine Penicillin C . represents
an anhydrous mousse system. Both formulas are designed for injection into the udder via the sphincter canals. CFC-12 and CFC-114 are used for the products
204
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 12. BABY CARE MOUSSE FORMULATIONS
Formula L 9abv Oil Mousse
xo 23.00
Deionized Water Mineral Oil
-
30.00
Medium Viscosity
Cetaryl Alcohol (and) Cetareth-20 C16-Cl8 Alcohols and C16-Cl8 Alcohol PEG 20 Ethers
10.00
Macol 124 by the Mazer Chemical Company Isodecyl Oleate and/or Myristyl Kyristate Ceraphyl 140-A and/or Ceraphyl 4 2 4 by Van Dyk h Co., Inc
LO .oo 3.35
Cyclomethicone Cyclic dimethylpoly (3-4) Siloxane Silicone # 3 U Fluid by Dow-Corning Corporation
Ethano1
12.00
S.D. Alcohol 40 (Anhydrous)
S.D. Alcohol 40 ( 2 0 0 ' ) by U . S . Industrial Chemical Div. Aloe Vera Aloe Vera Extract
-
0.25 100% Pure (90% A.I. Powder)
Aloe Vera 100% by the Terry Corporation Perfume Perfume selected for mildness
0.25
Xechyl p.Hydroxybenzoate Nipagin M by Nipa Laboratories. Ltd.
0.15
Hydrofluorocarbon 152 1.1-Difluoroethane
8.00
Dymel 152 by E.I. DuPonc de Nemours
&
Co.. Inc.
Zsobutane Isobutane A - 3 1 by Phillips Petroleum Company Concinued
3.00
Example Non-CFC Alternative Formulations
TABLE 12.
(Continued)
Formula H Babv Powder Mousse edients
x (w/wl
Deionized Water
35.70
Silica (Powder) Hi-Si1 233 Fumed Silica Anticaking Agent by PPG Industries, Inc,
0.30
Quaterniun-26 (Hydroxyethyl)Dimathyl(3-Hink Animal Oil Amidopropyl)
2.00
Chlorides Ceraphyl 6 5 by Van Dyk and Company, Inc PPG Laneth 50 Polyoxyethylene ( 5 0 ) polyoxypropylene (12) Lanolin Ether
0.50
Solulan by Amerchol Products Unit
0.40
Cetyl Alcohol Talc Talcum Powder
-
18.10
Impalpable
Altalc 200 Ethanol
32.00
S . D . Alcohol 40 (Anhydrous)
S.D. Alcohol 40 (200') by Shell Chemical Company Perfume
0.20
Hydrofluorocarbon 152 1.1-Difluoroethane
8.00
Dymel 152 by E.I. DuPont de Nemours h Co.. Inc.
Isobutane Isobutane A - 3 1 by Phillips Petroleum Company
2.80
205
206 Alternative Formulations and Packaging t o Reduce Use of CFCs
TABLE 13.
VAGINAL CONTRACEPTIVE MOUSSE N
S
Uxm
Nonoxynol 9
8.0
Lauricfiyristic Acids
2.5
Stearic/Palmitic Acids
3.5
Triethanolamine
2.2
Glyceryl Monostearate'
2.5
Polyoxyethylene (20) Sorbitan Mono-oleate
2.5
Polyoxyethylene (20) Sorbitan Monolaurate
3.5
Polyethylene 600 Glycolb
1.5
Polyvinylpyrrolidone K-30'
1.0
Benze thonium Chloride, USPd
0.2
Deionized Uater
67.6
Propellant A-46
5.0
Viscosity builder and foan stabilizer. bAverage molecular weight is about 600. 'Protective colloid. dBenzyldimethyl [ 2 - [ 2- (p.1,1,3,3-tetramechylbutylphenoxy)ethoxy]ethyl] Ammonium Chloride
Example Non-CFC Alternative Formulations
TABLE 14.
MOUSSE FOR MASTITIS TREATMENT Formula 0 % (w/w)
Ingredients Sodium Lauryl Sulfate (30% Active Ingredient in Water) (As Duponol WA Paste, or equivalent)
21.1
Polyethyleneglycol 400 Distearate
3.5
Triton X-100'
0.4
Sodium Palmitate/Stearate
0.4
Sodium Sulfate 10-Hydrate
0.2
Sodium Citrate %-Hydrateb
1.5
Neomycin Sulfate (as base)
3.8
Sodium Hydroxide (50% in Water)
--
to pH 9.2
q.s.'
Deionized Water
56.5
Propellant A-46
6.0
'Foam modifier . 'Sequestrant and stabilizer 'A sufficient quantity.
207
208 Alternative Formulations and Packaging to Reduce Use of CFCs
a v a i l a b l e in the U.S.. but an i n t e r e s t i n g t o p i c a l product. using dimethyl ether u the propellant was patented about 1980.
I t contains chlorhexidene
acetate o r gluconate plus a l i g h t - b l u e dye ( t o show the a r e a s t r e a t e d ) , i n a hydroalcoholic system.
After milking, it is used aa a germicide and the
c h i l l i n g e f f a c e of evaporating d i e t h y l e t h e r causes t h e s p h i n c t e r muscle t o
f r r d i a t a l y closa. preventing contamination of the udder quadrants and The product is e s p e c i a l l y
i n c i d e n t a l l y a l s o preventing some leakage of milk.
usaful f o r o l d e r
COWS
on automatic milking machines.
Pharmaceutical foams have been w e l l received f o r over a dozen s p e c i f i c a p p l i c a t i o n s . including hemorrhoid CreaCment. r e l i e f of teneamus i n deep vounda and e u cleansing.
When foam medicinals a r e t o be i n s e r t e d i n t o various body c a v i t i e s , i t i s o f t e n b e s t t o use a s p e c i a l cype of very b l u n t , a l l - p l a s t i c syringe. such a s
the model shown i n Figure 1.
e
5 OR 10 mL MARK
Figure 1. Foam Syringe Directions: To use the metering syringe, f i l l t h e b a r r e l with foam t o a l e v e l beyond t h e volume mark, minimizing any a i r pockets. Press t h e p i s t o n i n u n t i l it reaches the volume mark, removing excess from the nozzle t i p . I n s e r t : then slowly press the p i s t o n i n t o the f u l l e s t e x t e n t . The narrow t i p of the plunger serves t o minimize any wasted product remaining i n the nozzle a r e a , since such medications a r e o f t e n r a t h e r c o s t l y .
Example Non-CFC Alternative Formulations
209
Since dosage is directly affected by foam density, it is desirable to formulate a foam vith a density in the range of 0 . 0 5 t o 0.10 g/mL, using sufficient propellant so that the foam density at the beginning of product use vi11 not be more than 25% less than that near the end. Uniformity of propellant fill is also very important. For example, a Pamasol "Stepped Rotary" filler contains two concentrate filler heads. a crimper, and two propellant filling heads.
It vill.produce 35-40 meter-spray cans per minute, or 60-70
regular cans per minute, filling both product and propellant vith good accuracy. It is the filler of choice (vorldwide) for small, pharmaceutical products. Shave Creamg Shaving creams--thelast of the "mousse" products to be discussed--are more of a utility product than a personal care item. In the U.S., a 310-g dispenser can still be purchased on sale for less than $1.00, although most of the name-brand shave creams cost at least twice that much. Discovered in 1931 by Eric Andreas Rotheim of Noway, who pressurized certain soap solutions vith butanes, the shave cream vas reborn in the U.S. in 1948. It used from 6.5 to 8.5% of a CFC-12/114 blend.
In 1954, all but one
marketer changed over to 3.4 to 4.0% Propellant A-46. This particular blend of propane and isobutane has air-free pressures of 3.24 2 0.14 bar at 21°C. and 8.87 4 0.35 bar at 54.4'C.
At the time of its first production, it was
the highest-pressuremixture that could be used for atmospherically crimped, standard-strength aerosol cans. Table 15 gives the formulations for three typical shave creams. The usual shave cream formula is an 8 to 12% dispersion of sodium or potassium and triethanolamine fatty acid soaps in water, plus foam stabilizers, vetting agents, emollients, humectants, fragrance, preservatives. and sometimes special ingredients. Some fairly exotic materials have sometimes been used, such as fluoro-acrylic "super-detergents"for extra beard softening, and hyaluronic acid, a natural polymer that encourages the skin
210
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 15. SHAVE C R U n S
Ingredients
Formula A
Formula
Formula
B
C
U.S. Tradenames
Deionized Water
74.9
78.1
Lauric/Myristic Acids
1.5
0.7
Emersol 1 3 2 , e t . d .
Stearic Acid (Triple X)
6.0
8.0
Emersol 655 or 6 2 1
Laurylflyristyl Diethanolamine
0.5
.---
Schercomid SLM-S
-.--
1.5
Duponol WAT 30%
Sodium Hydroxide (50%)
----
----
Dow Chemical Co.
Potassium Hydroxide (45%)
_--_
0.4
Triethanolamine (99%)
3.9
3.0
Cetyl Alcohol, N.F.
0.5
----
-
5.8
2.5
Polyvinylpyrrolidone K30
_---
Mineral Oil. N.F. Grade
2.4
__-_ _-__
Methyl p.Hydroxyberuoate
0.1
0.1
n.Propy1 p.Hydroxybenroace
0.03
0.04
Fragrance
0.67
0.36
IFF #2651-AB
Lanolin Derivative
0.5
2.0
Lantrol-Malmstrorn
Propellant A-46
3.2
3.3
Phillips Petroleum
Sodium Lauryl Sulfate (30% Water Solution)
Glycerin
Note:
96%. U.S.P.
Union Carbide Corp .
Witco "Carnation"
These formulas may be packaged in tinplate or aluminum single-lined cans.
Example Non-CFC Alternative Formulations
21 1
renewal process and moisturizes the skin, to reduce the irritation of close shaving. Formula A is the highest quality of the three, followed by Formula C. Formula A io also the most costly, but the marketer has the option of making ouch claims as 'sodium
free," 'contains no alkali," or '100% organic." which
may be advantageous.
In addition to the foam stability provided by the sodium lauryl sulfate (often called SLS), WP K30, lauryl/myristyl diethanolanide (or coco-diethanolanide), and especially cetyl alcohol, formulation chemists may use Keltrol or Methocel 25KC thickeners, Monamid 150LU. Oariphat 170-C (acid zwitterion) and other ingredients.
The critical test for sufficient foam stability is
that the foam should not significantly drain or dry out from below the nose o f
the user in less than three to four minutes, even at low humidities.
It
should also be stiff, smooth and thick-textured, and form a 5 - g puff able to support a full-length pencil at a 5'
angle.
Some f o a m are dispensed hot,
either using reactive chemicals (such as sodium thiosulfate and 10% hydrogen peroxide, kept separate until the moment of use), or more commonly by using an electrical heating mantle. hot" at up to 85'C. required.
In such cases, the foam may be delivered "steaming
and quite a lot of extra foam stability agent will be
These hot foams represent only about 4% of the 210,000,000-unit
U.S. aerosol shave cream market. The choice of propellant is critical to success. At pressures of 2.5 bar or less at 21.C.
a secondary expansion will occur in the hand. which is
perplexing to the user.
Blends higher in pressure than Propellant A - 4 6 will
normally require a special, high-pressure-resistant can. The amount of propellant is also important to success. The use of too little propellant results in production of a higher density foam 0.12 g/mL),
(such as
and the situation will worsen as the dispenser is used up.
This is because emulsified propellant can escape into the expanding head space,
leaving less in the liquid phase to produce the foam structure. Conversely, over 4.0% hydrocarbon propellant will produce a relatively dry, airy foam with
212
Alternative Formulations and Packaging to Reduce Use of CFCs
poor vetability and smooth-out properties.
Excessive propellant may escape
during actuation, leaving the foam puff defaced, with a pock-marked, wrinkled or roughened surface. The noise level will be higher as the propellant tears the foam micro-structure during the escape process. Sop. work has been &ne
with alternative propellants.
Those with both
o i l and some water solubility produce less stable foams, such as HFC-l52a, but
the stability may be adjusted by using blends of HFC-152a and hydrocarbon propellant.
Dimethyl ether will not produce a foam.
Nitrous oxide generates
satiny foams with very fine micelle structures, as does carbon dioxide. Despite the l o w solubility (about l%), these foams remain reasonably uniform throughout package life, especially if only 60-65% product is placed in the can. Many unusual foams have been produced.
There are exploding foams,
bouncing types. crackling foams, and even anhydrous foams of astonishing durability.
Several anhydrous types are used for the application of topical
pharmaceuticals. Several food foams have been introduced, but the only really successful one is whipped cream, which is nearly always pressurized with approximately 1.2% nitrous oxide.
The s l o w growth of psychrophilic bacteria, even ac Z ' C ,
has posed a major shelf-life problem for many of these products.
One U.S.
filler has developed a process for producing sterile products, but enzymes will adversely affect even these products within a few months. Whipped food products that have not been marketed to any extent are pancakes (crepes), expanded mayonnaise, whipped syrups, ice cream toppings, chocolate milk additives. and alcoholic toppings for Irish Coffee and certain mixed drinks.
In the U.S.. the hydrocarbon propellants, nitrous oxide, carbon
dioxide. and nitrogen, are the only propellants permitted for food uses. some other countries, nitrous oxide is not allowed in food products.
In
One of
the key problems with food aerosols is that the final dispensers cannot be autoclaved to render the contencs sterile without causing the cans to burst.
Example Non-CFC Alternative Formulations
21 3
In the U.S.. these aerosol products fall into two distinct classes: the antiperspirant and the deodorant. Antiperspirants are considered drug products by the U.S. Food and Drug Administration because they have a definite physiological effect on the pores of the skin, and they are regulated accordingly. On the other hand, a simple deodorant consists of an alcoholic solution of a germicide, which does nothing except to reduce the population of
skin resident bacteria for several hours, thus inhibiting their ability to degrade certain ingredients in natural perspiration into malodorous materials. Antiperspirants also function as deodorants, because they reduce the pH value of the skin to about 3.2 to 4 . 2 at 3 S ' C , and this level of acidity inhibits
the proliferation of microorganisms.
In the U.S.. an aerosol antiperspirant must, by definition, act to reduce the rate of perspiration. More specifically, antiperspirants must reduce the output of the apocrine sweat glands by twenty to seventy per cent. These glands are actually located not only at the armpits, but in the ano-genital area, the eyebrows, and (in women) behind the ears. Despite the commercialization of aerosol antiperspirants in the past for more general body application, currently available products are labeled for underarm use o n l y . All antiperspirants have a physiological effect on the skin, but these effects vary widely with the formula, the consumer, testing conditions, time. and other factors. Sveat reductions even between the right and left underarm areas of a given person may be quite different. In 1978. the FDA issued a set of OTC (Over-The-Counter)drug regulations for antiperspirants, titled
"Guidelines For Effective Testing of OTC Antiperspirants" that defined an axillary sveat reduction study (2) as a proposed Monograph. It stipulated that an aerosol antiperspirant must reduce sweat by at least 20% after both 1 hour and 24 hours from the time of application in at least 50% of a minimum 15-person target population. The test conditions were 38°C and 35% RH (Relative Humidity) during the one-hour collection periods for each day of rhe five-day test cycle, and 22.2-C otherwise. Application time vas described a two-second spray under each arm.
as
214
Alternative Formulations and Packaging to Reduce Use of CFCs
Until the introduction of the more powerful aluminum chlorohydrate complexes in 1986. most aerosol antiperspirants fell into the 22-332; sweat reduction category.
By comparison, stick antiperspirants exceed 40% and some
roll-ons reach 65%.
However, a sweat reduction of 25% or more represents such
a dramatic improvement in the control of wetness that many users are quite satisfied with aerosol performance.
During the recent introduction of the
new, more potent antiperspirant materials, however, the suppliers stated that
they made these changer because of soma user dissatisfaction with product effectiveness, resulting in a sales reduction of the aerosol category over che years.
Aerosol antiperspirants have also had modest problems with "bounce
off." resulting in some nasal irritation, higher packaging costs, and occasional valve plugging.
Recent attempts to reduce ground-level ozone (smog-
related) have caused at least one state to study aerosol VOC emissions. During 1985. the Rehels Chemical Company ( U . S . ) announced their new line of REACH antiperspirants for aerosols and other dispensing forms.
These are
up to SO% more potent than the standard aluminum chlorohydrate complex; e.g.,
[A12(OH),]r,*2.5H20--which has an A1:Cl ratio becween 2.1 and 1.9 to 1.0, and an FDA permit level of up to 25% of the total product. The new REACH 101. 201, and 501 compositions represent commercial forms of aluminum chlorohydrate polymer that can be separated out of the mixture of polymers in the parent compound using liquid chromatography. The A1:Cl ratio is maintained. With the greater effectiveness (up 30 to 50%. depending on choice) formulators had the following options:
0
Use the new compounds at the former levels, for a 30 to SO% more effective product; or
0
Use reduced concentrations of the new compound, lowering the
effectiveness of the product t o the former level, but reducing formula cost and bounce off.
Example Non-CFC Alternative Formulations 215
Table 16 compares some representative antiperspirant product efficiencies .
In one form or another, aluminum chlorohydrate is the only active material nov used in aerosol products, but the specific polymeric compositions and their particle size distributions have gone through a transition from 1986 through 1989 that noy suggest that the REACH compounds have captured at least 80% of tha U.S. market volume.
In 1988. the aerosol underarm products sold
increased from 114 million units to 144 million, or 26%. alchough the aerosol industry grev by a comparatively small 6.8 percent.
This extraordinary growth
is said to have been the result of the availability of more effective products and well-advertised introductions by M e M e n , Bristol-Myers, and other marketers.
The aerosol share of the underarm market also grew, from 31% to 37Z.
The present products contain from 7 . 0 to 12.5% of various aluminum chlorohydrate complexes.
Without the addition of a dispersing system, the
suspended aluminum chlorohydrate would settle into a bottom layer between uses and would require long and difficult shaking to redisperse. Also. the material within the very bottom of the dip tube will not redisperse even with shaking, leading to valve plugging and consumer dissatisfaction.
Because of
this, all aerosol antiperspirant formulas contain a dispersing agent, normally a surface-treated form of montmorrillonite clay activated by the inclusion of a relatively polar ingredient such as ethyl carbonate or ethanol. With the correct combinations and balances and good compounding techniques, clogging problems can be avoided. Table 17 presents the formulation of a low-cost, low "bounce off" antiperspirant of above average effectiveness. Both the isopropyl myristate and silicone fluids of the formula shown in Table 17 are useful as inert carriers to transport the aluminum chlorohydrate to the skin surface and stick it there with a minimum of bounce off.
These
ingredients are also needed as slurrying material for the aluminum chlorohydrate to facilitate the production process.
216
Alternative Formulations and Packaging t o Reduce Use of CFCs
TABLE 16.
COMPARISON OF ANTIPERSPIRANT EFFICIENCIES
Generalized Composicion and Form 3.5%
Old CFC Formula (Banned in 1978)
X Efficiency First Day Fourth Day
25
10.0%
Hydrocarbon-Type Aerosol
25 2 7
12.5%
Hydrocarbon-Type Aerosol
30
29 5 7
10.0% Hydrocarbon-Type Aerosol (REACH 101)
44 2 8
57 5 6
10.0% Hydrocarbon-Type Aerosol (REACH 201)
3a 5 8
50 2 9
10 .OX
Hydrocarbon-Type Aerosol (REACH 501)
35 5 7
45 2 10
20.0%
Suspension Stick
-
Standard
40
20.0%
Suspension Stick
-
Rezal 36GP Active
55
25.0%
Roll-On Suspension - REACH AZP-703
62
Example Non-CFC Alternative Formulations
21 7
TABLE 17. AEROSOL ANTIPERSPIRANT
edients
% (w/wl
Aluminum Chlorohydrate (REACH 101).
8.00
Quaternium 18 Hectorfte (Bentonite 38)b
0.82
S.D. Alcohol 40-2 (Anhydrous)
0.80
Dimethylsilicone (500 centistokes (cstks)]'
1.50
Isopropyl ityriotated
1.00
Cyclomethicone F-251.
7.63
Perfume 011;
0.25
Propellant A-31 or A-46'
80.00
@ Berkeley Heights, NJ. (201)464- 1500. (An equivalent product is produced by the Uickhen Division of the Dov-Corning Corporation.) 'Bentonite 38 is a surface quaternized form of montmorillonite clay, offered by NL Industries. Inc. as "Bentone 38." 'Dimethylsilicone (500 cstki.) is available from Dow-Corning Carp., General Electric Silicones Division, and others. Purchase the anhydrous (clear) liquid. nef the emulsion forms. dIsopropyl Myxistare is sold by Van Dyk h C o . . Inc. and many ocher firms. *Cyclomethicone f-251 is a physical mixture of Cyclomethicone D-4 Tecramer 2 5 2 , and Cyclomethicone D-5 Pentamer 7 5 2 . It is available from the DowCorning Carp. 'The perfume oil is the marketer's choice. It must be purchased from a perfume house thar is advised that it will be used in a REACH 101 aerosol antiperspirant. and then tested for compatibility with the product. The percentage may vary, according to fragrance intensity and the marketer's preference. 'Propellant A-31 (with vacuum crimp) is preferred, giving a can pressure of about 2.5 bar at 21.1.C. The use of Propellant A-46 will provide an initial pressure of about 3 . 6 bar at 21.1.C (with vacuum crimp) and thus a delivery rate approximately 1% faster at the beginning of use. Preferential removal of air and propane through the vapor-tap orifice will reduce pressure to about 2.6 bar at 21.1.C when the dispenser is 50% empty, and to about 2.3 bar at 21.1.C at the point of incipient emptiness. (Continued)
218
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 17.
(Continued)
Notes :
18,000 cps. (Brookfield Viscometer; 10 rpm.)
1.
Concentrate Viscosity:
2.
Concentrate pH Value:
3.
Concentrate must be homogenized to remove probable clumps or clusters of oil-vatted aluminum chlorohydrate powder.
4.
REACH 101 is hygroscopic and must be protected from the moisture in
3.3
- 4.7 (1:lO v.
dilution in deionized water)
ambient air at a11 times. Once it is added to the oily concentrate it will no longer absorb moisture. The following recommendations apply: Keep drums closed except when sampling or using; 0
Do not remove packets of moisture-absorbent silica gel in drums, if present, except when adding REACH 101 to batch;
0
Add REACH 101 as quickly as practical, while still minimizing clumping; and
0
Rinse off tank walls of REACH 101 powder, irunediately after addition.
5.
If a U-t-C (Under-the-Cap) gasser i s used, the last 10% of the propellant must be added by means of a following T-t-V (Through-the-Valve) gasser in order to clear thick concentrate from the dip tube and avoid possible valve-plugging problems.
6.
All equipment touching the concentrate should be of 304 or 316 stainless steel. Tygofl hose. or approved rubber hoses in good condition.
7.
The concentrate is sufficiently thick or viscous that settling of the solids will be a slow process. However, continuous recycling of the concentrate is required, as well as some slow stirring of the concentrate filler bowl. Over-circulation, such as short-loop circulation during filler downtimes, is not recommended. It may cause localized heating and micro-splintering of the solid aluminum chlorohydrate.
Example Non-CFC Alternative Formulations 219
The isopropyl myristate improves feel (or handle) and texture. Being essentially nonvolatile, it helps the Dimethylsilicone (500 cstks.) carrier keep the underarm area lubricated for many hours. The other silicone materials are relatively volatile.
The F-251 blend 1 s
selected for a combination of effectiveness and lower expense.
They are used
to impart an extra measure of carrying ability and skin lubricity, preventing any tackiness development as the aluminum chlorohydrate slowly dissolves in perspiration films.
Having &ne
their work, they slowly evaporate, preventing
long-term excessive oiliness and the staining of clothing in the underarm area. The isopropyl mjmistate, and various silicone fluids also help the operation of the aerosol powder valve.
They reduce the amount of bulking
agent needed to prevent hard-packing of solids between product applications Finally, they provide spreading characteristics that help distribute the aluminum chlorohydrate more effectively across the dermal surface. If excessive amounts are used, the oil may coat the aluminum chlorohydrate so effectively that it cannot contact skin moisture and ing.
begin dissolv-
This will cause a lag betveen the time of application and the time
antiperspirancy becomes apparent. Fabric staining, "wetness." and cost will all increase if too much isopropyl alcohol and silicone fluids are used. Other materials have been suggested as replacements for these ingredients. For example, Croda. Inc. suggests replacing isopropyl myristate with their Procetyl AWS (a propoxylated/ethoxylated
ether of cetyl alcohol).
Union Carbide suggests using Fluid AP, and others have promoted such items as myristyl myristate ester and octyl palmitate ester. added at some risk.
Such ingredients are
For example, some samples of myristyl myristate contain
small amounts of unreacted myristic acid, which can seriously reduce or even eliminace the antiperspirancy of the aluminum chlorohydrate. The Bentone 38 surface-polarized montmorillonite clay is very finely divided and has the approximate formula NaCa[ (A1.Hg)ZSf,O,,] -Q-nH,O.
where Q is
220
Alternative Formulations and Packaging to Reduce Use of CFCs
a specific quaternary ammonium compound designed to increase surface charge and further promote suspending properties.
A
small amount of ethanol is added
to activate the polar surface and augment charge separation. When the balance is achieved, the Bentone 38 and ethanol system will slow doun the settling of the aluminum chlorohydrate and allow it to eventually settle into a lose, voluminous layer between product uses. or shake will then swirl the solids back into suspension.
A gentle inversion
This should be
checked for any new formula (even a new perfume in a tested formula) using glass compatibility equipment.
If the aluminum salts can settle into a hard,
obdurate mass--regardless of settling rate--the product will suffer from problems of reconstitution and probable valve plugging. Both scented and unscented antiperspirants are marketed.
The unscented
versions are sometimes preferred by men, and always by hypoallergenic persons. They are usually very lightly scented, despite the label, using approximately 0.04% of nondescript perfume oils to cover the slight chemical odors of the
other ingredients.
Some products contain encapsulated perfumes, in addition
to the "non-encap" perfume.
They provide longer-term fragrance release, as
moisture dissolves the modified polyvinyl alcohol (0.001"(0.025mm)-diameter) micro-capsules of additional fragrance. The aluminum chlorohydrate easily develops enough acidity under the arm to prevent the proliferation of skin-resident, odor-causing bacceria.
Thus,
no special microbicides need be added, except to treat cases of chronic hyperhydrosis or certain other dermal pseudomorphoses. The homogenization step for the concentrate-processing stage should be a one-stage, rather gentle one designed to break up clusters o € oil-saturated aluminum chlorohydrate. rather than to fracture the roundels of the salt itself. The roundels are already sufficiently fine-particled that they will not clog an aerosol valve.
But if they are broken up into a lot of "splinters,"
buildup and possible clogging might occur.
Example Non-CFC Alternative Formulations
22
Sample amounts of the concentrate should be made in the laboratory so that the viscosity and flov characteristics of the batch-making process can b
A variable speed, planetary, top-entering agitation system is needed for best results. When the povder is added and viscosity increases, considered.
all parts of the mixture must be agitated. The compounding procedure is as follows: Add the isopropyl myristate. through a 5-micron filter;
0
Add the Cyclomethicone F-251. through a 60- to 100-mesh screen; Begin agitation at about 75 rpm;
0
Begin recycling, out the bottom and back into the tank via a pipe that extends to the lower one-third, to prevent splashing.
The pump
in this system should be set at around 150 to 200 rpm to prevent shearing.
A Cuno or similar filter in this line will be bypassed
during the compounding stages;
0
Pre-weigh the Bentone 38 and add manually to the tank at a fairly slow rate, about one 20-kg bag per minute at most:
0
Agitate at least 15 minutes, until the Bentone 38 is dispersed;
0
Add the SD Alcohol 40-2 (Anhydrous);
0
Operators in face masks and protective clothing then add powdered aluminum chlorohydrate REACH 101 to the mix-tank at a rate of about 25 to 50 kgs per minute:
--
Build batch size around full-drum amounts of REACH 101 if possible, to prevent dealing vith partial drums,
222
Alternative Formulations and Packaging to Reduce Use of CFCs
--
Protective masks and clothing are needed because of che generation of irritating dusts during additions;
0
U t h e r quickly, add the dimethylsilicone (500 cstks) to the batch tank, using a suitable Tygon or rubber hose, so that deposited powder on the walls and &me
of the mix-tank can be rinsed down into
the batch; ~ d Perfume d Oil;
0
Agitate at least 15 minutes.
0
Arrange recycling line to pass product through stainless steel Cuno
Check for dispersion uniformity;
filter (coarse) and through either a Votator or Homogenizer to homogenize the lumps. Use a filter with about 0.13-mm spacings. Use a f l o w rate of 150 to 200 kg per minute;
0
Pass the finished concentrate into a stainless steel, agitated holding c a d . with a recycling line as close to the concentrate filler as practical.
1O'C
The temperature will have increased some 5'
to
during rotating or homogenizing, but it should not be allowed
to be over 40'C. The valve is often supplied by Precision, Seaquist, Valois, Aeroval, Summit, or other major manufacturers in a rounded edge, powder-valve design.
In the U.S., a large, 20-mm diameter, white, one-piece button is used.
It i s
ordered separately from the valve and applied by hand (rarely) or by an automatic button tipper, often to line up with the 180' reverse-directional dot on the crown of the valve cup. A prototype valve is one with a 0.46-mm stem orifice. 0 . 6 3 x 0 . 4 6 - m vapor-tap body, neoprene gasket. and 0.50-mm straight-bore actuator button. The delivery rate can be changed dovnvard if desired by using a 0.50-mm vaportap orifice instead of the 0.46-mm size.
Many formulators check several
larger-volume products on the market and decide which ones have the best spray
Example Non-CFC Alternative Formulations
223
pattern. delivery rate, and other characteristics they require.
They then contact che appropriate valve company, identifying the product, and ask for a sample valve mada to the same specifications.
Unless it is a customized
component (which is rare, except perhaps for color) the valve-maker will always comply.
Tvo forms of the REACH 101 antiperspirant powder, differing only in particle size distribution, have been used in aerosols:
0
MICRO-DRY "REACH 101" (Reheis):
Standard.
Impalpable.
More than
99.8% of cha particles are smaller chan 7 4 p ;
0
MICRO-DRY "REACH 101" (Reheis):
Ultrafine.
At least 99.8% of the
particles are smaller than 5 0 p . A filtration step, using a Cuno or equivalent cartridge filter of 0.13-mm
retention, removes agglomerates, oversized particles, tramp cellulose fibers (from bags), and other extraneous solids from the finished batch of concentrate.
Experience suggests that the Standard, Impalpable grade is quite
satisfactory and somevhat less of a potential problem in terms of the rate of moisture pickup during handling.
Hovever. it is always a good idea to contacc
the suppliers (Reheis and Dow-Corning Corporation, in the U.S.) and ask for recommendations and literature. The aerosol can may be a necked-in 200-201/202~406or 509 or 514-mm can in the U.S. market. which is equivalent to a 51-51/52~111or 140 or 148-mm can elsewhere. The necked-in version is a marketer preference, based mainly on aesthetics, not on technical or functional requirements. "straight-wall" cans are also acceptable.
The so-called
Because the low-density hydrocarbon
propellants are nearly always used at levels approximating 75%, it is customary to place a LOO-to 115-gram fill weight into the can size just described. In the U.S.. the necked-in cans have a 50.70 2 0.25-mm industry specifi cation for the diameter of the top double seam.
This relatively difficult
224 Alternative Formulations and Packaging to Reduce Use of CFCs
specification reflects a need for uniformity to prevent full-diameter straight-wall cover-caps from fitting too tightly or too loosely when applied over the seam. The cans are generally of minimal tinplate throughout, with a single lining and usually a stripe over the welded side seam.
Adherence to Good
Manufacturing Practicer (GMP). which includes code legibility, is a general requirement for this Over-The-Counter drug product. The personal deodorant (or underarm spray deodorant) complements the antiperspirant.
It is often used by those who have either constant or
sporadic skin irritation problems with antiperspirants because of their salinity, astrsngency or acidity, or by those for whom underarm perspiration is either not a problem, or cannot be controlled by antiperspirants because of the environment or ty-pe of activity, The basic personal deodorant formula consists of a germicide, fragrance, ethanol solvent, deionized water (sometimes) and propellant.
The standard
propellant in the U . S . is either isobutane, or a mixture of up to 37 vtX propane in isobutane.
In Europe, both hydrocarbon and dimethyl ether pro-
pellants have been used.
Various HFC and HCFC propellants could technically
be used, but their higher cost has so far effectively precluded their use. Four representative formulations are given in Table 18. The size of the personal deodorant market is now about 55,000,000units in the U.S.. 34,700.000 in 1988 in Japan, and relatively small in Europe.
The
containers are similar in size and logo to the antiperspirant aerosols, and are sometimes purchased by mistake because of this. Most major marketers offer both products in two or three sizes and in both scented and unscented
Example Non-CFC Alternative Formulations
TABLE 18.
Insredients
225
PERSONAL DEODORANTS
Formula A
Formula B
Formula C
Formula
D
Irgasan DP-3000. Germicide Genzthionium Chlorideb Kethyl p.Hydroxyberuoate n.Propy1 p.Hydroxybenzoate Benzyl p.Hydroxybenzoate Propylene Glycol, U.S.P. Dipropylene Glycol Zinc Phenolsulfonate' Fragrance
S.D. Alcohol 40-2 (Anhydrous) Deionized Water Sodium Benzoate Isobutane (A-32) Propellant Blend A - 4 6 16 wt% Propane in Isobutane Propellant Blend A - 7 0 37 wt% Propane in Isobutane Dimethyl Ether
'2,h,4"-hydroxydiphenylethe bBenzyldimethyl [2-[2-(p.1,1,3.3-tetramethylbutylphenoxy)ethoxy]ethyl~ Ammonium Chloride. 'Zinc Sulfocarbolate.
226 Alternative Formulations and Packaging to Reduce Use of CFCs
versions. The packaging requirements for the hydrocarbon-propelled formulas are designed to give a fairly fine-particled, low delivery rate spray, using a vapor-tap valve with (typically) a 0.33-mm diameter orifice and a mechanical
For the dimethyl ether products (as in Formula D of Table 18). very efficient valves are required to break up the large amount of water
break-up button.
The Precision Valve Corporation's 2 x 0.50-mu "Aquasol" stem valve.
present.
0.50-on KEST (Mechanical Break-Up. Straight Taper) button, and butyl rubber stem gasket valve may be used.
The supplier should be contacted for specific
recoanandations, but sprays of 60p average particle size are obtainable.
The
somewhat higher cost of dimethyl ether in most areas can be justified by its ability to incorporate significant amounts of water in solution, giving the
-
feeling of excessive vctness.
The flame projection of this formula will vary
somewhat with valve selection, but it is generally a 100- to 150-man small,
sputtering light blue plume or flare.
A
cologne is generally considered'to be
dilut
form of the perfum
or
sachet product, containing from 1.5 to 6 . 5 % of essential oil or fragrance compound.
The true perfume may contain from 6 . 5 to 14.0 percent.
The carrier
is almost always ethanol, generally anhydrous ethanol, and the propellent is often a hydrocarbon type.
For perfumes. which are smaller and more costly
than colognes, the glass or aluminum dispenser carries a meter-spray valve able to dispense about 0 . 0 5 gram per actuation.
A typical 20-gram fill will
offer about 400 actuations to the user. The European innovation known as the deo-spray is a form of cologne and has the typical cologne composieion. inferred from the generic name.
No deodorant is present. as might be
Packaged in lined aluminum cans holding as
much as 200 grams, the deo-spray or deo-cologne provides an inexpensive option for spraying one's skin or clothing with a relatively low-cost but still acceptable fragrance. Some deo-sprays are made especially for
use
by younger
children and are labeled accordingly. Plastic caps resembling flowers and animal heads have been used for added appeal. somewhere between a cologne and a perfume.
Finally, the sachet spray falls
It contains approximately 4 to 8%
227
Example Non-CFC Alternative Formulations
fragrance compound formulated t o as l i g h t a c o l o r a s possible t o prevent the s t a i n i n g of l i n g e r i e . handkerchiefs, and o t h e r f a b r i c s .
Two typical cologne
formulas a r e presented i n Table 19. Glass has been t h e accepted standard f o r colognes s i n c e t h e o r i g i n of the aerosol c o l o p i n 1953.
While p l a i n g l a s s c o n t a i n e r s of up t o 125-mL
capacity have been m a r b r e d , glass b o t t l e s of g r e a t e r than 30-mL capacity a r e u s u a l l y p l a s t i c coated. container is o f t e n used.
I n the U.S.. the Wheaton Aerosol Company's "Lamisol"
I t has a vinyl-based covering that firmly adheres t o
the glass s u r f a c e , making It more resistant t o f r a c h l r i n g i f dropped and helping t o contain g l a s s fragments and flammable vapors if the container does break.
A t present.
the U.S. Department of Transportation l i m i t s t h e s i z e o f
non-metallic aerosol dispensers t o a capacity of 118.3 mL (wichout a s p e c i a l exemption). The use of the OPET, P e t a s o l , and similar p l a s t i c b o t t l e s is being s t u d i e d i n t h e U . S . . Japan, and Europe.
Based on b i a x i a l l y - o r i e n t e d polyethy-
lene t e r e p h t h a l a t e , these b o t t l e s o f f e r l i g h t n e s s , g r e a t break r e s i s t a n c e , c l a r i t y , translucency. o r opacity, and more freedom of shape and design than glass.
Their very l i g h t n e s s has been vieved as a marketing d e t e r r a n t . since
buyers a r e accustomed t o t h e s o l i d i t y and v e i g h t i n e s s of g l a s s a s a q u a l i t y attribute.
These b o t t l e s cannot be used f o r s t r o n g s o l v e n t s , such a s dimethyl
e t h e r , s i n c e they l o s e s t r e n g t h r a t h e r r a p i d l y a t temperatures o f over 60'C. and may s u f f e r from permeation e f f e c t s when used with some formulations,
In
England, h a i r sprays (not too d i f f e r e n t from many cologne formulas) have been marketed s u c c e s s f u l l y a s 2OO-gram f i l l s i n OPET b o t t l e s . The l e v e l s of HFC-152a (CH,*CHF,) or HCFC-22 (CHClF,) used i n Formula A i n Table 19 a r e considered minimum l e v e l s .
The vapor pressures of boch
p r o p e l l a n t s a r e suppressed when they a r e added t o ethanol. an e f f e c t reduced when water is incorporated a s a t h i r d ingredient. contains 13% deionized water.
This i s why Formula
A
An aerosol valve with maximum breakup power i s
used f o r a l l cologne formulations,
228 Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 19. COLOGNE FORNUATIONS Formula A
Formula B
(X)
(X)
Fragrance
4.00
4.00
Di-n.buty1 Phthalate
2.00
_-_-
Sodium Saccharinate'
0.01
FD&C and/or D&C Dye' Solution'
0.09
-----_-
65.00
76.00
Ingredients
S.D. Alcohol 40 or 3% (Anhydrous) Deionized Water. HFC-152a or HCFC-22 Isobutane A-31 Packaging mode:
Glass
Aluminum
'The Sodium Saccarinate (or a similar synthetic sveetener) is added to nullify the rather tart bouquet of the ethanol. the U.S., these are Food, Drug, and Cosmetic-approved dyes or Drug and Cosmetic-approved dyes in the form of a stock solution of various concentrations. The solvent is generally deionized water, but propylene glycol and/or a preservative may be added as w e l l .
Example Non-CFC Alternative Formulations
229
Perfumes, deo-sprays, sachets, and related products have relatively similar formulations.
Fragrance is deposited on an animate or inanimate
surface with high efficiency.
The spray must be relatively wet, but still
retain cosmetic elegance. Although dimethyl ether could be.used in fragrance products, and there are those who claim it imparts a cleaner, fresher odor, especially when water is included, others suggest that the propellant itself has a stronger odor than the purified hydrocarbons, and certainly much higher than HFC-l52a, which has almost no odor at all.
Fillers in various parts of the world continue to
use CFC-12/114 blends for perfumes and colognes, partly because of the greater importance of reduced final-product flammability when dealing with a frangible material such as glass.
Some of these fillers are not set up yet to safely
handle flammable propellants.
In time, they will have the option of convert-
ing to nonflammable HCFC-22 propellant or to one of the nonflammable future alternative types, such as HFC-134a.
The latter is a modest solvent and is
virtually odorless. Perfumes are extremely complex mixtures of both natural and synthetic materials, and it is rare that all of them are soluble in the complete aerosol formula.
In some instances, these resinous substantives will only precipitate
after several days or weeks.
When they do, they usually agglomerate into
fairly hard masses, readily capable of causing sputtering, distorted spray patterns or even plugging the aerosol valve.
In a clear glass container the
precipitation can be seen, and it gives a very negative image of product quality . An early industry practice was to store the complete formulation in a covered 2.000-liter tank at - 1 O ' C
€or several days, then to filter out the
dregs enroute to the product filler. With the flammable propellants, this technique is no longer practical, although the complete Concentrate can certainly be held for a time at room temperature and then filtered free o f precipitates.
The perfume suppliers are well aware of the problem and can
sometimes provide fragrances that have been tested to show that the addition of hydrocarbon propellants to the filtered concentrate vi11 n o t cause any
230 Alternative Formulations and Packaging to Reduce Use of CFCs
further precipitation.
The marketer should always make the "two-week test,"
which is to prepare the finished formula in either a clear glass aerosol, or in a clear glass product-compatibility tube of about 100-mL capacity, holding it for one week at 35 to 4O'C.
and then for one week at 2 to 4'C.
The sample
unit is then evaluated for clarity or haziness, for precipitation, and for good odorour stability when compared with a freshly prspared standard in
glass.
The darker-colored fragrance products seem to be more prone to
precipitation. Uhen fragrance products are packaged in small aluminum c a m . the cans should be lined with an epon-phenolic or similar material.
Otherwise. the
bare aluminum metal may have a reducing effect on aldehydes and certain other sensitive perfume ingredients. Some perfume components are known to cause o r enhance corrosion reactions, especially the citrus types. such as bergamots and citronellal bases.
Test packing is essential.
Formulations that contain
water are especially critical. HOUSEHOLD PRODUCTS
General C o m e n u
The "household products" segment of the U.S. aerosol industry reached a total of 1 , 4 2 4 , 1 0 0 , 0 0 0 units in 1 9 8 8 , accounting for 48.8% of the aerosol industry total and making this the largest category. details.
See Tab.le 20 f o r
In Japan, the same segment amounted to 1 2 3 , 5 5 4 , 0 0 0 units in 1988,
amounting to only 2 5 . 5 % of the industry total.
In that country. the largest
market share of aerosols ( 4 4 . 3 % ) is held by personal care products. In the U.S., the term "household products" includes a11 consumer aerosols except for pesticides, personal care items, and foods and drugs.
They are
administered by the Consumer Product Safety Commission (CPSC). which is a federal agency created in 1972 to handle the Federal Hazardous Substances Act of 1960. the Poison Prevention Packaging Act of 1970, and other laws.
Among
other things, they recommend pre-market testing of aerosols for flammability. inhalation toxicology, skin and eye toxicology, ingestion toxicology, and
Example Non-CFC Alternative Formulations
TABLE 20.
231
HOUSEHOLD AEROSOL PRODUCTS SOLD IN THE U.S. DURING 1988
Product Type
Number of Units ~~
10.5
Paints, primers, and varnishes Paint strippers. “snow, dacoratives
% of Total ~
~
24,500,000
0.8
Roou deodorants and disinfectants
181,200.000
6.2
Cleaners (glass, oven, rug, tile)
167,200,000
5.8
Laundry products (starch, pre-wash)
146,000,000
5.0
Waxes and polishes
129,100,000
4.4
Other (shoe polishes, anti-static spray)
26,800,000
0.9
Refrigerant C air/conditioner refills
90,700.000
3.1
5,700,000
0.2
Cleaners (automotive upholstery)
16,300,000
0.6
Engine degreasers
27,000,000
0.9
Lubricants and silicones’
92,900,000
3.2
Spray undercoatings
15,700,000
0.5
Tier inflator C sealants
34,400,000
1.2
Carburetor C choke cleaners
57,100,000
2.0
Brake cleaners
29.700.000
1.0
Engine starting fluid
30,900,000
1.1
Other automotives 6 industrials
62.600.000
1.5
1.424,100.000
48.gb
Uindshield C lock de-icers
‘Penetrating oils, demoisturirers. rust-proofers. mold release agents, tablet machine lubricants, etc. bThe U . S . 1987 figures vere 1,326,000,000 and 48.7%. Note:
During 1988, household aerosol products increased by 7.4% in unit volume, compared with a 6.8% growth of the aerosol industry as a vhole.
232 Alternative Formulations and Packaging to Reduce Use of CFCs
(sometimes) dermal corrosivity. Additional clinical studies may be needed in some cases.
If the studies are not run, or if the overall results are not
placed on the label in a prescribed f o k t , the agency will impose severe sanctions on marketers whose products are found to be injurious to consumers. In
addition. any torts (lawsuits) will be much more readily prosecuted by
plaintiffs against marketers whose product labels are found to not meet federal standards.
As with all U.S. aerosol products, the primary content declaration must be in units of weight (Avoirdupois ounces and pounds), although a volume or weight subsidiary declaration in the
metric system is acceptable.
The size
of various signal words, statements of hazard, precautions, directions, weight declaration and other informational statements is controlled by CPSC regulations. Most household aerosol products consist of a dispersion of solids or liquids in a continuous liquid phase.
For paints, a group of finely divided
pigments is suspended in a resin/solvent/propellant solution.
For starches
and fabric finishes, as well as cleaners, a colloidal suspension or emulsion of various organic materials is prepared in an aqueous solution.
These
products are dispensed in various ways, as shown in Table 21. Water-out emulsions are used for most cleaners, but oil-out types a r e used for air fresheners, the foam-type charcoal lighters with approximately 5% water, and certain other products.
The choice of propellants is very broad.
In addition to all the propellants described above, isopentane (boiling point
-
29.8'C),
helium, oxygen. and even 0 . 2 ~ filtered compressed air have been
used for a few specialty items.
In the U.S.. CFC propellants may be legally
used for the product types shown in Table 4.
Sweden, Norway, and Austria, f o r
example, have much shorter lists of exempted or excluded products, while most other countries currently have either a production/importation restriction, o r no limitations at all.
In contrast with personal care products. pesticides, and most others, household products often have very low quantities of propellant in the
Example Non-CFC Alternative Formulations
TABLE 21.
HOUSEHOLD AEROSOL PRODUCT DELIVERY MODES
Product Air Fresheners Hard Surface Cleaners Foam-Type Charcoal Lighters
Delivery Mode
Spray Foaming Spray Foam
Lubricants; Decorative Strings
Stream
Boat Horns: Electronic Cleaners
Gas
Silica-based Absorbent Powders Caulking Compounds Lithium Stearate Grease Talc-based Lubricants: Wind Direction Indicators for Golfers
Liquid/Solid Spray Paste Gel Powder
233
234
Alternative Formulations and Packaging to Reduce Use of CFCs
For example, window cleaners often have 3 to 1%. starches may have
formulas.
5 to 6%. certain heavy-duty cleaners may have 6 to 8%. and rug or upholstery
shampoos usually carry 8 to 10 percent.
The minimum amount is determined by
the following factors: Gassing machine accuracy; Propellant seepage out of the dispenser during its shelf life; Propellant separation from the product during use. going into the expanding head space to try and maintain pressure; Propellant discharge during use, because of its slight solubility or entrainment in the concentrate; and Consumer misuse, causing momentary release of propellant phase through the valve. Perhaps the lowest level of hydrocarbon propellant was 1.8% n.butane, used for a low-foaming window cleaner. After several years, the pressure and use level were increased. As a general rule, the amount of nitrogen or compressed air that can be pressure-filled into an aerosol can is about 1 gram per LOO mL of capacity. At levels much above this, the pressure becomes excessive. Household aerosol products have a greater history of consumer complaints than do other aerosols. This is because they have longer shelf and service lives, often contain more powerful solvents, are stored in a greater diversity of places and conditions, and are sometimes deliberately- misused.
Examples of
misuse are painting graffiti and the deliberate concentration and inhalation of paint vapors and other aerosols as well.
In the U.S.. the "Extremely
Flammable" label seems to be limited to household aerosols. The conditions of use have a profound effect on the degree of flammable hazard to the consumer or his property.
Paints should only be used where
235
Example Non-CFC Alternative Formulations
adequate ventilation is available. A concrete block moisture sealer was banned by CPSC in 1974 because it vas loo# fl-ble
in composition and two to
three large cana vere used at a time for basement waterproofing purposes. Several lives vere lost, and over a dozen houses burned down.
A fabric protectant product, designed to spray a fluoroacrylic oil and water resistant film onto entire upholstered sofas and chairs, could not have been responsibly marketed in f l d l e form (using acetone or ethanol as the solvent, for example).
This product has the folloving formula:
UPHOLSTERED FURNI'NRE STAIN-GUARD SPRAY
35
Fluoroacrylic or other stain-repellant active ingredient
1#
n.Buty1 Acetate (Extender)
918 58
1,l.l-Trichloroethane
-
Inhibited
Carbon Dioxide
Since 96# of this formula is nonflammable, it has enjoyed great success in an inportant niche area; however, it has an Ozone Depletion Potential (ODP) of about 0.15.
(The ODP is a relative-index of ozone destruction efficiency;
the value reflects the atmospheric lifetime and the chlorine content of the molecule.) Household products have pressures that vary from about 2 to 8 bar at
21.1'C.
which is the equivalent of 6.7 to 12.7 bar at 54.4.C.
Those formulas
that have the higher pressures often use nitrogen. nitrous oxide, or carbon dioxide as the propellant and are designed for use at very low temperatures (such as -1O'C).
Applications include windshield de-icing, engine starting,
and dispensing a non-slip surface on ice for cars stuck in snow or ice.
These
gases will still retain about half their room-temperature pressure when the dispenser is chilled to - 1 O . C .
whereas most of the other propellants will sink
down to such low pressures that the products become essentially unusable.
236 Alternative Formulations and Packaging to Reduce Use of CFCs
Window C
l
w
The vindov cleaner, developed in 1954, was the first of a large array of vater-based cleaning sprays, such as hard surface cleaners, whitewall tire cleaners, oven cleaners, bathroom (basin, tub, and tile) cleaners, and laundry cleaners for spot applicatfon to difficult stains on textiles before general cleaning in the washtub or washing machine. Uindov cleaner products are water solutions with from 5 to 12% hydroxylic solvents, to which a very small amount of detergent is added.
Iso-propanol
(C,H,OH) is nearly always used because it is a good grease solvent and its odor is associated with cleanliness.
Additional odorants are optional.
marketers prefer to add arpmonium hydroxide (‘&,OH)
in
Some
concentrations of up to
0.3% of the commercial 29% solutions of ammonia (NH,) in water.
The ammonia
actually does little cleaning, but consumers associate its odor with cleanliness.
Sometimes a minor amount of fragrance may be included.
Oily materials
and excess amounts of detergent must be avoided, or a film may be left on the glass surface, giving a halo effect in some situations. The percentage of propellant in the formula is usually 3.2 to 5.0% isobutane. The organic grease-cutting solvents may include butoxyethanol (C,H90-
CH,OH),
isopropanol (C,H,OH), propylene glycol monomethyl ether [HOCH,-C(CH,)H-
OCH,) , and propylene glycol monobutyl ether (HOCH,-C(CH,)H-OC,H,].
The ratio
is about two parts of isopropanol (C,H,OH) to one part of one or two of the solvents.
The detergent selection is more critical to success.
Apart from the detergent benefit, a certain amount of foam structure is needed to show where the product has been applied and also to prevent dripping from vertical surfaces,
If the foam is too voluminous or stable, the wiping
cloth will simply push it around, without removing it by absorption. Also, too little detergent will reduce cleaning action, while too much will cause streaking on the cleaned glass surface.
Some typical window cleaner fonnula-
tions are shown in Table 22 and two specialized glass cleaner formulations are shovn in Table 23.
Example Non-CFC Alternative Formulations
TABLE 22.
237
WINDOW CLEANER FORPNIATIONS Formula A
Formula B
Formula C
99%
4.0
5.0
4.0
Propylene Glycol Monoethyl Ether
3.0
2.5
Sodium Nitrite
0.1
0.2
0.1
Ammonia (29% NH, in Water)
0.2
0.2
0.2
InnredienCs
Isopropanol
-
Butoxyethanol Sodium Lauryl Sulfate'
Lauryl Di-isopropanolamide Ammonium Lauryl/Myristyl Alcohol EO 3:l Sulfate
Deionized Water
89.0
88.5
90.0
Isobutane A- 31
3.5
3.3
3.5
'Such as Sipon WD, a product of the American Alcolac Corp.
238 Alternative Formulations and Packaging to Reduce Use of CFCs
ANTI-FOGGING OR ANTI-STATIC C U S S CLEANER FORMUUTIONS
TABLE 23.
Formula A
Formula B
Dioctylester of Sodium Sulfosuccinic Acid'
0.05
0.08
Silicone Glycol Copolyme?
0.30
0.40
Alkoxylated ( 8 ) n.nonylpheno1'
0.10
--__
Propylene Glycol Monoethyl Ether
3.52
3.49
8.00
10.00
0.03
0.03
Ingredients
Isopropanol
-
99%
Morpho line Deionized Water
84.00
82.00
Isoburane A-31
4.00
4.00
'As Aerosol OT-LOO. by the Chemical Product Division of the American Cyanamid Company, or Monavet MO-70E by MOM Industries, Incorporated. bAs Dov Corning 193 Surfactant, by the Dow-Corning Corporation. Watersoluble, gives gloss, non-tackiness, anti-fog, surface tension depression, and anti-static properties. 'As Triton W-30 by the Rohm 6 Haas Company, gives added grease removal and cleaning pover.
239
Example Non-CFC Alternative Formulations
The products in Table 22 are used mainly for windows, but they can also be employed to clean refrigerators, stove tops, kitchen counter tops and other hard-enameled, painted, or chinaware surfaces.
Because of their special
properties and somewhat higher cost. the aerosols in Table 23 are used more for bathroom mirrors (to prevent steaming), where anti-static properties are desired, and where a relatively glossy, polished appearance of the glass surface is desired.
One version of this type of product is eyeglass lens
cleaner, with dispensers in the 15-gram size that use metered spray valves delivering approximately 50 microliters per actuation.
These products give
about 300 actuations. Despite a general preference for the small sizes, containers holding as much as 460 grams of "Lens Cleaner
-
Antifog" are on the
market.
The self-pressurized starch was developed around 1958 and used about 4% of highly refined corn starch as the essential ingredient.
Some of these
starches can be dispersed into the aqueous phase at temperatures as low as 30 to 35'C.
but others may require pre-cooking a 20% starchfiorax (Sodium
Tetraborate 10-Hydrate: Na2B,0,*10H20) with live steam at 4 bars and 150'C. The resulting thin paste. now concentrated to 18% solids as the result of some condensation of the steam, drops into the batch-making tank containing agitated water and is quickly dispersed. The other ingredients are then added, after which the pH is adjusted to about 8.2 at 2 5 ' C . Starch dispersions have been corrosive to cans, but if ingredients with a low chloride content are selected, and SOlnetimeS if a modest amount of corrosion inhibitor is added, a single-lined can is sufficient for a three-year shelf life.
CWO-
or
One starch formula that uses 0.04% sodium benzoate
inhibitor has been successfully marketed in a plain 4.48 g/mz (0.20 lb/ftz) container.
If the starch contains a significant amount of chloride ion
corrosion promoter left over from sodium hypochlorite (NaClO) bleaching operations, corrosion can become a significant problem and a double-lined can must be used, along with 0.20% sodium nitrite or similar inhibitors. Three typical starch formulations are shown in Table 24.
240- Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 24.
SPRAY STARCH M R U U U T I O N S
Ingredients
Formula A (%1
Formula B
Formula C (%)
(%')
Amizo No. 513 Pearl Starch
2.30
----
----
Penford Gum 290 or Equivalent
_---
2.75
-___
EO-Size 5795 Starch or Equivalent
----
----
3.00
Sodium Tetraborate 10-Hydrate
0.30
0.40
0.45
Silicone emulsion LE-463, 346 or equal. (60% Active Ingredient)
0.40
0.50
0.45
Silicone antifoam emulsion, as SAG-470 by Union Carbide
0.15
0.10
0.10
Sodium Nitrite or Sodium Benzoate
0.15
----
0.10
Fragrance
0.02
0.03
0.03
Gluraraldehyde (50%) or Formaldehyde (37% in Warer)
0.04
0.05
0.03
Optical Brightener; as Tinopal 4BM
0.02
--__
----
Deionized Water
91.20
91.70
90.00
Isobutane A-31
5.50
6.00
5.0L
Note:
Adjust pH to 8 . 4 f 0.2 at 25'C. using triethanolamine (99%) solution of sodium hydroxide. The optical brightener ingredient is now rarely seen. and has only slight marketing appeal.
OK
a 102
It adds c o s c
If available, glutaraldehyde is preferred over formaldehyde, since rhe latter is less effective as a microbicide and may be a low-order carcinogen. Glutaraldehyde is marketed by Union Carbide Corporation.
241
Example Non-CFC Alternative Formulations
The sodium tetraborate, added as the 5- or 10-hydrate, combines chemically vith the starch to give it better properties, such as less buildup on the sole plate of the iron, and also functions as a corrosion inhibitor. The silicone emulsions increase the easy slip of the iron over the cloth, so that the user has less fatigue and almost no wrinkling or bunch-up problems.
The
starch foam should quickly absorb into the textile, and should not be pushed around by the iron.
If this is not the case, either a 10% or 100% silicone This ingredient consists of a silicone oil that
anti-foamant is added.
contains billions of tiny sharp splinters of silica (SiO,).
The silica acts
to puncture the foam bubbles so that they quickly collapse.
Antifoams are
used in about half of all starch products. Since starch solutions are nutrients for bacteria, yeasts, molds, fungi, and rickettsia, it is necessary to perform the following steps during production: Pasteurize the deionized water, or filter it at 0.2g to remove microorganisms.
(Resistant strains of pseudomonads are hard to kill
chemically, but they are eliminated by heating for one minute at 4O’C or higher.) Sanitize the batch-making tank, the concentrate filler, and all the pumps, filters, piping, and other equipment. Do not hold the starch concentrate for more than
72 hours, and then
only in covered tanks.
-
Flush the deionizer beds periodically with a strong formaldehyde solution, to prevent the proliferation of microorganisms on the resins.
Some fillers also run a Total Plate Count (TPC) study on starch batches and finished aerosols. Since these tests require 48 hours for a reliable result, the batch will normally be packed into cans and corrective action will be severely limited. The best result w i l l indicate that there are “fewer than
242
Alternative Formulations and Packaging to Reduce Use of CFCs
10 microorganisms per cubic centimeter of product." sibility of proliferation still exists.
Therefore, the pos-
Experience with starches, fabric
finishes, mousse products, and others that can support microbial growth suggests that the possibility of growth is low once the aerosol can has been packed.
For example, non-facultative aerobic bacteria generally die from lack
of oxygen.
In the rare instances of starch contamination. bacteria have
caused 'ropiness," or little tendrils of retrograded material in the product, leading to valve problems and odors from triethylaine and other substances. Host starch formulas use 0.03 to 0.035% Formalin (37% formaldehyde, HCHO, in water).
Sodium o.phenylphenate is still occasionally used.
preferred macerial is glutaraldehyde [CH,(CH,*CHO),].
However, a
This material has very
broad spectrum activity, is low in cost, effective at concentrations even lower than fornaLdehyde, and does not sometimes sting the nose of the user during the ironing process. A significant amount of work has gone into refining the designs of valves that will be best for starches. The best spray pattern, for instance, is a "doughnut" or torus shape, without "hot spots" or areas of extra-heavy product concentration.
This pattern gives the most uniform spray density as the spray
is sprayed across the fabric. Host starches in the U.S. now use either vertical-acting or toggle-type valves whose button and stem are separate components.
In general, the buttons
are of the two-piece type. vith a plastic insert of 0.46 to 0.50 mm orifice design.
Hovever. a new "pseudo-mechanical breakup" one-piece button by the
Precision Valve Corporation is now being used commercially. During product development, valve candidates are tested against production or commercial control units for the incidence of valve problems. test often involves 72 dispensers and lasts two weeks.
The
The caps are left off
to enhance product evaporation at the valve.
Protocols differ, but one starts on a Konday. with 48 cans being sprayed for 5 to 10 seconds on the following schedule:
2, 2, 3 , 2, 2, and 3 days, and
243
Example Non-CFC Alternative Formulations
24 cans being sprayed every seven days.
The results are recorded in the
following ways: Clear (Normal); Streams--thtee seconds or less--then clears; Streams--sustained streamer--over three seconds; and Plugger. If more than two sustained streamers or one plugger are encountered, the valve or formula should be adjusted to be more reliable.
If the control,
using a different valve, gave acceptable results, this suggests that the experimental valve needs improvement, not the formula. Starch products work better on cottons and on 50% cotton and 50% polyester fabrics than on textiles of higher polyester content, i.e., the socalled "synthetics." Some marketers have developed Fabric Sizing or Fabric Finish aerosols especially for these synthetics. As the market for synthetics diminished during the last LO years or so, consumers began to discover that they liked the performance of these fabric finishes on straight cottons and high-cotton blends.
They did not have the relative stiffness of the starches,
but gave the fabrics lubricity, a better feel or handle, and an impression of heaviness and brighter colors, making them seem more like new garments.
since
the product was based on sodium methylcellulose gums, the Fabric Finish produced a somewhat higher-quality spray and had a higher-quality image than the starch.
It is a useful supplementary product, and sales were estimaced to
be about 12 to 142 of the starch market in the U.S. in 1988.
Table 25
presents a formulation for aerosol fabric finish. Heaw-Duty Hard-Surface C l e m This product vas an outgrowth of the vindow cleaners. versions:
It is sold i n t w o
one with a microbicide, and the other without such an ingredient.
If the cleaner has a microbicide and is labeled accordingly, in the U.S. it falls under the jurisdiction of the Environmental Protection Agency (EPA)
244 Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 25.
FABRIC FINISH FORMLTLATIONS
INGREDIENTS
FORMULA (X)
Sodium Methyl Cellulose (Combination of low and medium-lw viscosity products). Technical Grade preferred.
0.9
Polyethylene Glycol (Mol.Wt. 400)
0.9
Coco-p-amino-propionic Acid (60% in Water)'
0.02
Dimethylsilicone Emulsion (60% in vater)
0.3
Silicone Anti-foam (100%)
0.03
Ammonium Hydroxide (29% NH, in vater)b
0.02
Glutaraldehyde ( 5 0 % in vater)
0.03
Sodium Nitrite
0.05
Fragrance
0.05
Deionized Water Isobutane (A-31)
92.70
5.00
'Deriphat 151. by Henkel Corporation. %sed to neutralize the Deriphat 151 (Acid) and adjust the pH value to 8.6 2 0.2 at 25'C.
245
Example Non-CFC Alternative Formulations
FIFRA and is subject to a heavy burden of microbiological testing, label
review, and confidential formula disclosure before marketing.
The delay
period is currently one to two years, and an annual registration fee must also be paid to EPA and to state agencies.
Some marketers elect to include
microbicides in their products and sell them without making any claims, since the cost differential is extremely small. The first hard-surface cleaner was introduced around 1961.
The products
are characterized by a combination of non-ionic and tetrasodium ethylenediaminetetraacetate (Na,EDTA) detergents, plus various alcohol- or glycolbased solvents in a water base.
Two typical hard-surface cleaners are shown
in Table 26. The tetrasodium EDTA, present at 1.90% (Formula A) and 1.52% (Formula B) is effective at removing calcium carbonate, which it does by a sequestering action, producing soluble calcium ethylenediaminetetraacetate [Ca,(EDTA)]. The dissolution process is a slow one if the lime has any significant thickness; therefore, the main thrust is one of preventive maintenance. deposits are similarly dissolved.
Rust
These uses suggest various bathroom
applications. Higher pH versions, sometimes with 25% deodorized kerosenes added, have been used as whitewall tire cleaners. Anhydrous versions, generally contain4
,
7
>
ing about 5% non-ionic surfactant, 20% xylenes, 72% deodorized kerosene, and 3% carbon dioxide are used for cleaning the exterior of car engines. After use. the cleaner can be flushed away with tap water.
It is generally ad-
visable to perform the cleaning operation outside on a cool engine that is not running.
Hydrocarbon propellants, such as propane (A-lOe), have been used for
these products, but they are not recommended because of their flammability. A
second anhydrous version, in this case not containing any surfactant
materials, is carburetor and choke cleaner.
It typically contains 60% toluene
or (better) xylenes, 30% diacetone alcohol or acetone, and 10% propane.
It is
obviously extremely flammable, and should be used in small amounts and with care in an open and well-ventilated area.
The engine should be cool and
246
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 26.
HARD SURFACE CLEANER FORMTIATIONS
INGREDIENTS
FORMULA A
FORMULA B
(%)
(X)
0.50
Atlas C-3821 Detergent Tergitol 15-S-9 .(Non-ionic surfactant)
0.50
Tetrasodium EDTA (38%
5.00
Triethanolamine
-
in water)'
8%
1.00
Propylene Glycol klonobutyl Ether
5.00
Sodium Meta-Silicate 5-Hydrate
0.10
Sodium Sesqui-Carbonate Morpho1ine
4.00
6.00
0.10 0.20
Ammonium Hydroxide (29% NH, in Water)
0.15 1.00
Sodium Hydroxide ( 5 0 % ) or Citric Acid (50%)b
9.S.S
9.5.c
Fragrance
0.10
0.15
82.10
79.90
7.00
7.20
Deionized Water Isobutane (A-31)
'Although a specific surfactant was mentioned, any one or more of che following may be used:
-
Linear primary alcohol polyglycol ether (9 to 12 mol ethylene glycol (ETO); average) ; Linear secondary alcohol polyglycol ether (9 to 12 mol ETO: average); or Nonylphenol polyoxyethylene (9 to 13 mol ETO; average).
These reagents are used to adjust pH value to 10.5 2 0.2 at 2 5 ° C
. . (a sufficient quantity). Quantum sufficrf
247
Example Non-CFC Alternative Formulations
turned o f f .
Any excess should be removed before t h e car i's r e s t a r t e d .
use of a no&-ble
The
p r o p e l l a n t , such as HCFC-22 o r carbon dioxide, would a c t
t o make the o v e r a l l product only s l i g h t l y less fl-ble.
The f i n a l v e r s i o n of a hard-surface cleaner is oven c l e a n e r . both c a u s t i c formulas and 'pre-caustic"
formulas.
There a r e
The c a u s t i c ones use from 4
t o 8Z sodium hydroxide a c t i v a t e d by t r i e c h a n o l m i n e t o c u t through the v a r n i s h - l i k e d e p o s i t s of grease and food s p a t t e r s on oven s u r f a c e s .
The o t h e r
form containa alkali metal acetates and sometimes o t h e r organic salts i n a
water and s u r f a c t a n t s l u r r y .
The product is sprayed on the oven s u r f a c e s ,
a f t e r vhich the oven is closed and heated.
This causes t h e organic s a l t s t o
pyrolyse v i a a d i s t i n c t l y N o - s t a g e process, producing the oxide, carbon dioxide, and water.
The oxide then hydrates t o the hydroxide form, which
begins d i s s o l v i n g t h e baked-on greases and ocher residues.
' the
Table 27 presents
formulations of oven c l e a n e r s .
I
The c a u s t i c nature of Formula A in Table 27 allows it t o r a p i d l y corrode aluminum s u r f a c e s , and t h i s is o f t e n mentioned on l a b e l s .
Under U.S. regula-
t i o n s , i f an oven cleaner contains more than 2% of a c a u s t i c such a s sodium hydroxide, the dispenser m u s t be f i t t e d v i t h a c h i l d - r e s i s t a n t c l o s u r e .
The
same r e g u l a t i o n s permit one exempt package s i z e designed f o r homes without
c h i l d r e n and f o r a d u l t s v i t h physical problems l i k e a r t h r i t i s vho would o t h e r v i s e have g r e a t d i f f i c u l t y using the product.
In p r a c t i c e , t h e market-
place has shown a s t r o n g preference f o r the products wichout the s p e c i a l c l o s u r e s , so that dispensers t h a t have t h i s f e a t u r e a r e nov only a token p a r t of the o v e r a l l s a l e s p i c t u r e .
S e l f - c l e a n i n g ovens i n the U.S., Europe, and
o t h e r a r e a s w i l l reduce s a l e s of aerosol oven c l e a n e r s .
The o t h e r type of heavy-duty cleaner is designed f o r the s p e c i a l t y cleaning of t e x t i l e s .
The b e s t known is the pre-laundry cleaner s t a i n
remover, which is sprayed d i r e c t l y onto a s t a i n and onto the inner neck band of s h i r t s , s h i r t c u f f s , and o t h e r a r e a s where d i r t and grime seem t o concentrate.
After spraying, the garment may then be laundered.
Some formulations
contain enzymes f o r the more e f f e c t i v e removal of proteinaceous s t a i n s ; e . g . ? grass s t a i n s o r bloodstains.
Others use a mild detergent system and claim
248
Alternative
Formulations
TABLE
and Packaging to Reduce Use of CFCs
27.
OVE.'I
CLEANER
FORMULATlO~S
FORMULA A
INGREDIENTS
FORMULA B
Potassiwa Formate
6.0
Potassium
6.0
Sodiwa
Acetate Hydroxide
Calcium
Dodecylbenzene
Compatible Sodium
Sulfonate
0.5
Thickener
0.2
Nitrite
Triethanolamine Tetrasodium
-99% EDTA
Deionized
\later
Isobutane
(A-31)
.38%
0.2
1.0 1.0 87.8
78.3
5.0
6.0
Example Non-CFC Alternative Formulations
249
that the treated garments may be stored for several days before washing, if
50
desired. The two major formula types are anhydrous and water-based. generally contains 25 to 40% water.
The latter
Originally, soil removal was accomplished
by u s h g 20 to 25% perchloroethylene, in addition to the usual anionic/nonionic detergent system and hydroxylic solvents. The perchloroethylene (Cl2C-CC1,)
w a s a major benefit t o the cleaning activity, doing such a good
job, in fact, that many users complained that their clothes were cleaner and whiter where the product was applied than in the other areas. Some wondered if the product contained a bleaching agent.
The marketers maintained a
service for taking care of shirts and other garments submitted to them by consumers for correction or replacement, and what they normally did was to immerse the entire item in the concentrate for a few minutes, rinse it off. dry the garment and return it.
The super-cleaning ability of the aerosol
product had removed soils that resisted ordinary cleaning methods and that had built up on the garment over months of use. turning the cloth slightly grey or slightly tan.
Eventually, the perchloroethylene vas deleted, after the Bruce
Ames “mutated Salmonella“ test suggested that it might be a carcinogen and after a number of more odor-conscious consumers complained that traces of the chlorocarbon odor could be detected in clothes even after they were automatically washed, dried, and ironed.
The two main formula types of textile
cleaners are illustrated in Table 28. The isopropanol functions as a mild cleaner, but (just as importantly) as a foam destabilizer and suppressant. Ethanol may also be used for this purpose.
In either case, percentages may vary according to the foaming
tendencies of the overall formula. CarDet and Rue Cle anel: This unique product was introduced around 1964 by S. C. Johnson & Son, Inc.
It is presented in a very large can, such as the 75x192 mm (USA:
300x709) or the new, necked-in 72x261 mm (USA:
211-213/214~1005).which have
250 Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 28.
PRE-LAUNDRY CLEANER FORMllATIONS
INGREDIENTS
FORMULA A
FORMULA B
Linear primary or secondary alcohol polyglycol ether [2 to 4 mol ethylene glycol (ETO)]
12.0
Linear primary or secondary alcohol polyglycol ether (7 to 10 mol !ZTO)*
12.0
10.0
Diethylene Glycol Monomethyl Ether
12.0
5.0
Sodium Laurate/Kyristate
0.4
-
4.0
5.0
20.0
786.7
Isopropanol
99%
Lov-odor n.Paraffinic or iso.Paraffinic C,, Hydrocarbons) Solvent (Clo
-
Ammonium Hydroxide (28% NH, in Water)
0.5
Fragrance (Typically lemon/lime)
0.5
Enzyme Concentrate (Optional)
1.0
Deionized Water Propane A-108 or Propellants A-85 Carbon Dioxide
0.5
30.1
7.5 2.8
'Hay be replaced with octyl or nonyl phenol polyoxyethylene (9 to 13 mol €TO) or other non-ionics of similar HLB value.
Example Non-CFC Alternative Formulations
251
capacities of about 820 and 980 mL, respectively. This allows one can to clean a carpet of maximum area. The products
use
sodium lauryl sulfate, which acts to pull the dirt and
grime out of the carpet fibers and then dries so that vacuum-cleaning can effectively remove it.
An
emulsified polymer is included to prevent rapid re-
soiling of the absorbent fibers. Table 29 gives a typical carpet cleaning formula. Intensive wetting of the warp and voof of the carpet is not desired, as would occur if sodium stearate/palmitate soaps were to be used.
Excessive
wetting lengthens drying time, and might also cause mold formations at the base o f the carpet or rug. The sodium/magnesium lauryl sulfate combination vets only the surface of the fibers, where most of the dirt is collected. In particular, the magnesium lauryl sulfate helps surround the dislodged dirt into a more friable, dried mass on the surface of the fibers, for easy removal with a vacuum cleaner. The sodium lauryl sarcosinate functions as a corrosion inhibitor, more
or less specific to lauryl sulfate ion and ethoxylated or propoxylated Lauryl sulfate moieties. However, for it to function well, there must be a virtual absence of chloride ion, bromide ion, and copper ion. The highly purified "toothpaste" grade of sodium lauryl sulfate (SLS) is acetone extracted or otherwise treated to remove any chloride ion that may be present, depending on the method of synthesis used.
Sodium nitrite has often been added to these
formulas as an additional corrosion inhibitor. The upholstery shampoo is a related aerosol product that uses such detergents as sodium lauryl sulfate or morpholinium stearate, plus ingredients such as lauryl-monoethanolamideas a corrosion inhibitor and foam stabilizer. The foam is worked into the upholstery covering with a rough cloth or softbristle brush, then allowed to dry before removal. A water-wipe is often used to remove the last bits of product, so that a slightly soapy feeling will n o t be noticed.
252 Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 29.
RUG AND CARPET CLEANER PRODUCT FORMUIATION
INGREDIENTS
FORMULA
Sodium Lauryl Sulfate (very l o w in Chloride Ion)‘
1.60
Magnesium Lauryl Sulfate (very l o w in Chloride Ion)b
1.20
Sodium Lauryl Sarkosinate
-
(30% in Water)‘
Styrene Kaleic Anhydride Copolymer
-
(15% in Water)
3.00 20,00
Optical Brightener; as Calcofluor SD (Optional)
0.02
Ammonium Hydroxide (28% NH, in Water)d
0.16
Fragrance
0.08
Deionized Water
66.44
Isobutane A-31
7.50
‘As Maprofix 563, by the Onyx Division of Witco Chemical Co. b A s Maprofix Mg. ‘As Maprosil 30.
*Used to adjust the pH value to 9.8 2 0.2 at 25’C, although up to about 1.5% may be used if the clean odor of ammonia (NH,) is desired.
Example Non-CFC Alternative Formulations
253
d Absorbent Fabric Cleaaerp A relatively unique aerosol product uses the extreme absorbency o f very
finely divided silica povder to literally soak up stains by capillary action. Silica, which has been made by the pyrolysis of silicon tetrachloride, is able to absorb hundreda of times its own veight of various liquids, even greases and gels, and this principle is used here.
The silica, in the form of an
slurry in 1,l.l-trichloroethane, is sprayed onto the The solvent quickly evaporates, causing the silica
essentially nonfl-ble fabric to be treated.
powder to absorb any available liquid materials.
After complete drying, the
loaded silica is brushed off the cleaned fabric, using light strokes, so as not to embed it in the fiber matrix.
The aerosol dispenser often comes with a
special plastic cap whose top is molded to have 100 to 200 thin, comb-like tines or bristles. 'The cap is used to brush off the silica.
A typical formulation follovs: ABSORBENT SILICA CLEANER FO-TIONS
Fumed Silica Povder 1,1,1-Trichloroethane Isopropanol
-
99%
6.00
68.00 10.00
Fragrance. Propane A- 108
0.05 15.95
The selection of silica powder and a valve with optimum design features are keys to success, since with an incorrect combination, valve plugging may occur.
The user can correct this problem only 40 to 60% of the time.
There
are also considerable problems with evaporation, concentrate l o s s e s , t o x i c o l o gical response to l.l,l-trichloroethane vapors (unless used in a vellventilated room) and weight control in the manufacture of these products, so that one should not undertake their manufacture lightly.
254
Alternative Formulations and Packaging to Reduce Use of CFCs
These cans, when actuated under totally non-conductive conditions, will build up a static charge in the 67,000 to 285.000 V range, based on the results of one fairly large study.
This does not adversely affect the
consumer in any way, but if a filled can is j m e d , defective. or otherwise quickly discharges the contents in a gas house vhile momentarily not grounded, the spark to a nearby grounded surface may cause ignition of the discharge plume, perhaps with serious consequences. No viable corrective methods for this phenomenon have yet been devised.
The air freshener was the second aerosol product to be developed commercially, after insecticides.
It was marketed in the U.S. as early as 1948,
mainly by oil companies, and then by chemical specialties marketers such as the Colgate-Palmolive Company.
The formulas were initially combinations of 1%
fragrance, 15% low-odor petroleum distillate, and 84% CFC-12/11 ( 5 5 : 4 5 ) , until about 1961, when the S. C. Johnson & Son, Inc. firm began to market their line
of "Glade" Air Fresheners in a water-based form. These formulations now make up the largest segment of this category.
The remaining segments are the
"super-dry" sprays, typically containing 99% propellants, and the alcoholic types that average about 50% ethanol.
Typical examples of the three versions
are presented in Table 30. The use of dimethyl ether propellant in Formula B is justified by the increased solvency of perfume resins that might otherwise precipitate. As mentioned earlier, Formulas 0 and C have a Volatile Organic Compound
(VOC) level of essentially 100 percent. After February 28, 1990. the State of New Jersey (U.S.) has forbidden the marketing of these formulas unless the VOC content is somehow reduced to 50% or less.
The use of 1.1.1-trichloroethane
(not a VOC. though it has a potential for stratospheric ozone depletion) is not permitted.
Ultimately, it may be necessary to use a combination of
something like 6 parts water and
** parts HFC-152a (replacing 50 parrs
Propellant Blend A-60) to be in compliance with the regulations. will have a major effect on the retail cost of these products.
of
This change
Example Non-CFC Alternative Formulations
255
AIR FRESHENER FORMULATIONS
TABLE 30.
INGREDIENTS
FOXHUIA A
FORMULA B
FORMULA C
(X)
(Z)
(X)
Fragrance
1.00
1.50
2.00
Odorless Petroleum Distillates
6.28
Lanpolamide 5 Liquid (Croda, Inc.) PEG LPnolinamide and PEG Lanolate ester 50% in Deodorized Kerosene (HLB 3.65)
0.72
-
6.00
-
38.00
S.D. Alcohol 40-2 (Anhydrous). Sodium Benzoate
0.15
Deionized Water
59.85
Propellant Blend A-60b
32.00
Dimethyl Ether
4.00
90.00
50.00
8.50
.Specially Denatured ethanol, where 400 g of tertiary butanol [(CH,),COH] and 42 g of brucine sulfate are added to every 3,600 liters of anhydrous e thano1. bContains typically 62 weight percent isobutane. 2 weight percent of n.butane and 40 weight percent of propane.
256
Alternative Formulations and Packaging to Reduce Use of CFCs
. . This category has often been compared with air fresheners, but there are more differences than similarities. First, the "D/D" products are regulated by the U.S. &PA. so that planning and formula development should be carried
out at least three years before the marketing phase begins.
Secondly, most of
the label is given to a description of the formula, disinfectant claims, and directions for disinfecting hard surfaces. The ability of the product to function as a space spray is limited by the low levels of propellant used, since the main use is as a surface spray, and labeled uses limit space spraying to storage rooms, closets, and other enclosed spaces for deodorizing purposes only.
(Fragrance benefits are not mentioned on the label, although a
pleasant fragrance is always included, even in "Hospital Strength" D/D products.)
Two formulation types and two propellant types are currently in
use.
The
base product contains either an o.pheny1-phenol system or a quaternary ammonium disinfectant system in a hydro-alcoholic solution.
Either 5% carbon
dioxide or about 20% hydrocarbon propellant blend is used as the pressurizing medium.
In terms of units sold, the o.pheny1-phenol and carbon dioxide syscem
is probably the most popular. The EPA requires that the labels of these products list the active ingredients, plus certain other data.
An example from the label of one such
product is shown below: Active Ingredienrs: n-Alkyl (60% C,,, 30% C,,, 5% C,,, 5% C18) dimethyl benzyl ammonium chlorides . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . n-Alkyl (68% C,,, 32% C,,) dimethyl ethylbenzyl ammonium chlorides . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Ethanol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . n-Alkyl (92% C,,, 8% C16) n-ethyl morpholinium ethyl sulfate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Inert Ingredients: 46.7282 Contains sodium nitrite
0.072% 0.0722 53.088% 0.040%
Example Non-CFC Alternative Formulations
257
The first two ingredients are available as BTC 21234, which is sold as a 50% active ingredients solution (and in other strengths) by the Onyx Division of the Witco Chemical Company.
Similarly, the last n-Alkyl compound is sold as
Atlas 6-272, generally as a 352 active ingredient solution, by IC1 America,
Inc. Two examples of these formulas are provided in Table 31. The quaternary smmonium chloride products came along well after the market for D/D aerosols vas well established and approaching 100,000.000 units sold a year in the U.S.
The strengths and weaknesses of their antimicrobial
spectrum of efficacy is different from that of o.pheny1-phenol and its close derivatives, as would be expected.
Also, since the quaternaries are much less
volatile than the substituted phenols, the protective effects may last longer. This may be important when considering regrovth potential for molds in leather, wood, books, and other relatively porous substrates.
No one has
attempted to market a product containing both microbial types, perhaps because of the degree of toxicological and microbiological testing that would be required, Since they have chloride ion (a strong corrosion promoter) double-lined cans and heavy amounts of strong corrosion inhibitors have been required to achieve an adequate shelf life for the quaternary ammonium formulations.
For
some time, combinations of sodium nitrite and morpholine were preferred for
the inhibitor system, but after it vas found that up to about 10 parcs per million of morpholinium-N-nitrosamine (a carcinogen) could be formed in s i t u over one year of room-temperature storage, marketers acted to change the sodium nitrite to sodium benzoate and eliminate the reaction.
. srnfectant . Cleaners This type of product vas partially covered under "Hard Surface Cleaners" (see Table 26). but the disinfectant version adds a new dimension of cleaning that is generally appreciated by the consumer.
Most of the larger marketers
of heavy-duty cleaners are able to cope vith EPA's requirements for premarketing registration, plus federal and state fees, and have preferred this type of presentation.
The disinfectant cleaner is really nothing more than
258 Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 31.
DISINFECTANT/DEODORANT FORMULATIONS
INGREDIENTS o.Pheny1-phenol (98% purity) BTC-212%
FOBMTIA A
FORMULA B
(X)
f%)
0.110
(502 in water)'
0.288
Atlas G-271 ( 3 5 X in water)'
S.D. Alcohol 40-2 (Anhydrous)b
0.114 73.380
52,068
Fragrance
0.110
0.110
Sodium Benzoafe
0.200
0.220
Morpholine
0.200
0.200
21.000
25.000
Deionized Water
22.000
Propellant Blend A-40' Carbon Dioxide 'For chemical compositions, see preceding page. bFor chemical composition, see note 'a' of Table 30. '10 w t X propane and 90 wt X isobutane.
5.000
Example Non-CFC Alternative Formulations 259
the standard type, except for the inclusion of 0.20% or so of biocidal
material in the fomula.
When a quaternary microbicide is used, the formula
has to be adjusted to eliminate incompatible anionic surfactants that might precipitate the active cationic moiety.
Some remain acceptable, as will be
seen in the formulation presented in Table 32. Normally, two cypes of valves are used for both these and the regular hard surface (basin. bath, and tile) cleaners. The can may be used in different positions, including some where the dip tube may protrude into the gas space.
The simplest and least costly approach is to use a valve with a
very large diameter, a .jumbo" dip tube, with an inside diameter of about 6 . 4 mm.
For the relatively long cans in general use. such tubes will contain 7 to
8 grams of product.
If the container is turned upside down--for instance, to
more comfortably spray the base of a toilet bowl--the special dip tube will hold sufficient product for about 6 seconds of spray time.
After this, gas
will be emitted, signalling the consumer to reverse the can for a second or In the second approach one might use the Sequist Valve Company Model NS-
wo.
36 (Ball-check) valve. A &-am diameter stainless steel ball travels in a short plastic slot. just below the valve.
With the can upright. an orifice ac
the bottom of the slot is closed off, forcing the product to travel up the dip tube and through the valve.
With the can inverted, the ball closes off an
orifice at the opposite end of the slot. This acts to plug the opening from dip tube to valve and at the same time opens a "vapor-tap" type orifice directly into the valve chamber. The valve has only two minor deficiencies: it always leaks slightly becween the plastic and the ball, to give a vapor-tap effect, and secondly, it works poorly when the can is in an essentially flat position.
The price is significantly higher than that of the standard valve
or jumbo dip tube valve. A good delivery rate for the hard-surface cleaners is about 1.23 g/sec at 21.C.
ture.
at the 460-mm vacuum crimp pressure of about 2 . 5 4 bar at that tempera-
A valve with a 0.46-mm stem and 0.41-mm W-ST button will provide che desired rate.
260 Alternative Formulations and Packaging to Reduce Use o f CFCs
TABLE 32.
DISINFECTANT CLEANER FORMULATIONS
INGREDIENTS
FORMULA (X)
Sodium Meta-Silicate 5-Hydrate
0.10
Tetrasodium EDTA (38% A.I. in Water)'
4.12
BTC 2125H (50% A.I. in
0.40
Sodium Benzoatc
0.10
Sodium Tetraborate 10-Hydrate
0.10
Morpho1ine
0.20
Ammonium Hydroxide (As 29% NH, in Uater)
1.10
Atlas C-3821 Non-ionic Surfactant'
0.50
Butyl Cellosolve (or similar)d
6.00
Potassium Hydroxide (45% A.I. in Water)
0.05
Fragrance
0.15
Deionized Uater
80.18
Isobutane A-31
7.00
'Tetrasodium Ethylenediamine-tetraacetate, such as Cheelox BF-13, or Versene 30 (Dow). bSee previous pages f o r complex formula of ingredients.
'By IC1 America. Inc.
dBy Union Carbide Corporation. be used.
Propylene Glycol Monomethyl Ether may also
Example Non-CFC Alternative Formulations
261
Products In 1988, the U.S. paints and coatings industry marketed approximately 325,000,000units, ranging from very small touch-up paints to large-size units for domastic or industrial furniture finishing. A substantial number of filling plants specialize in self-fill or contract filling operations. It is a complex area, vith five main categories: enamels, lacquers, varnishes, stains, and primers, vith subgroups of each. Large numbers of colors have also to be Considered. The largest sales are for the alkyd- and acrylic-base paints. Both are available in anhydrous and water-based formulations, although the water-based techniques are better developed in some countries than others, as is the use of dimethyl ether as a paint propellant. The formulas to follow illustrate a bronze metallic specialty lacquer (anhydrous). tvo
alkyd types and an acrylic type.
The last three are based on some
excellent work by W o n t that has been widely distributed. The term lacouer refers to a coating that dries by the simple evaporation of the solvent system. Originally, it related to the cellulosic varieties, but these have been almost completely displaced by the thermoplastic acrylics. The acrylics have better resistance to mild chemicals, weather. and sunshine. They are a preferred base for various metallic finishes (aluminum. bronze, and gold powder finishes) because of their low acid number and water-white color. Four different paint formulations are illustrated in Table 3 3 . A
prototype valve that might be evaluated is the Newman-Green Model R-10-
123 (0.33-rn vapor-tap), but with a butyl rubber seal gasket. The actuator is
a No. 120-20-18. This valve delivers the four products shown in Table 3 3 at about 0.95 g/sec at 21.1.C. During the development of various paint aerosols, alterations in the formula or valve may be required if the applied product exhibits low gloss, blushing, sagging, bubbling, peeling, deleafing of metallics, valve plugging, poor adhesion, low durability, or other problems. For example, adding more xylenes to Formula A would slow down the final drying of the film, resulting in better smoothness and higher durability. The disadvantage must be weighed against the two advantages, keeping in mind that the consumer will note the
262
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Alternative Formulations and Packaging to Reduce Use of CFCs
s
bl
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2
0
C
U
rl
0
v
rl W
0
-1
m
c
Example Non-CFC Alternative Formulations 263
2
CI
0
U
264 Alternative Formulations and Packaging to Reduce Use of CFCs
disadvantage rather soon
after the product is used, but may not detect the
other differences until later, if at all. Paints and coatings are generally packed with a small glass marble that helps agitate settled material back into a uniform dispersion. Also, to prevent premature use by children or others, a tamper-resistant and tamperevident valve cover or protective cap is used.
The outer cap is often colored
the same as the product within the can, or it may carry a self-adhesive top label to help the customer make selections. ture P
o
w
The original aerosol furniture polishes were introduced around 1950. They contained self-polishing floor waxes in a simple oil-in-water emulsion form.
In 1955. silicone emulsions were included, since they added lubricity
and made the rubbing out process much easier.
They also improved the sheen
and conferred water resistance to the polish.
At first, formulators added an
intermediate viscosity silicone, such as Dow-Corning DC-200 dimethylsilicone fluid (1,000 cstks), at a low-volatiles level about the same as that of wax: 0.7 to 1.5% of the total.
But as they found that silicones soaked into the
polishing cloth more readily than wax, they began to increase silicone levels. In addition, it was found that combinations of lower- and higher-viscosity silicones functioned better than the single intermediate viscosity type.
The
higher-viscosity silicone added shine or brilliance, but too much caused the polished surface to be subject to marking.
Two illustrative examples are
shown in Table 3 4 . The preparation of furniture polish concentrates can present fire and explosion hazards, especially if the more volatile aliphatic hydrocarbons are used, such as Isopar C. which has a flashpoint of 5'C. Isopar C to 80'C
Heating batches of
or so to facilitate the dissolution of waxes has caused four
major explosions and subsequent fires.
This is because very heavy vapors o f
the hydrocarbon seep over the tank rim. fall to the floor, and spread outward until a spark or fire source is contacted.
Less than 1 volume percent of
Example Non-CFC Alternative Formulations
TABLE 3h. ~~
FURNITURE POLISH FOWUIATIONS
~~
INGREDIENTS
FORMlLA 'A
FORMULA Bb
(%)
(X)
Wax S and Wax N (1:l ratio) Hoechot
1.25
1.25
Silicone Emulsion LE-461 (50% A.I.) UCC
1.40
1 40.
Silicone Emulsion LE-462 (50% A.I.) UCC
0.35
0 35
Arlacel C (Non-ionic surfactant) IC1 Am.
0.15
1.25
Isopar C or E (C, or C, iso.paraffinics) Exxon Oil Company
2.00
Lemon Oil. Technical Grade
0.75
0 60
Glutaraldehyde ( 5 0 % A.I.) UCC
0.05
0 03
Sodium Nitrite
0.05
0 05
Deionized Water Isobutane A-31
86.00
7.00
33
ooc
44 67
17 50
'Oil-in-water version. %ater-in-oil version.
265
(Better product; more costly.)
'Any n-paraffinic, iso.paraffinic, or multi-brancheate low-odor hydrocarbon may be used, at 12 to 36%. About 20% is an average.
266 Alternative Formulations and Packaging to Reduce Use of CFCs
flammable vapor in air is required for ignition.
Air-tight compounding tanks
and good ventilation is required. A related product is the wood paneling cleaner, conditioner, and polish. Pre-finished plywood wall panels, natural wood kitchen cabinets, and similar surfaces have relatively thin varnished or lacquared surfaces compared vith furniture, so that the use of water-based polishes like those just described vould result in some water penetration of the wood, and the finish vould be gradually lifted or peeled.
As a result, these products are anhydrous and de-
emphasize the use of wax-type ingredients.
The formulation in Table 35
provides good gloss, sealing, and detergent resistance. W
w
l
d De-Ice=
The windshield de-icer spray is a product representat re of automotive aerosols.
zens of
The most effective de-icer is methanol (CH,OH), and it
is used to some extent. despite its vell-known toxicity and the corresponding need for special labeling under various U.S. government regulations. such as the CPSC regulations. Isopropanol [(CH,),CHOH]
and n.propano1 (CH,-CH,-CH,OH)
are less hazardous but are less effective and more costly.
Since a simple
alcohol or alcohol/water de-icer would allow refreezing of the liquid to occur as soon as the alcohol was sufficiently diluted or evaporated, it is customary to add a certain amount of glycol to formulas.
Here again, ethylene glycol
(HO-CH,-CH,-OH) is the most effective, but it also is quite poisonous, so propylene glycol [HO-C(CH,)H-CH,-OH]
is used instead.
If very thin ice films are dissolved by an anhydrous alcohol/glycol product. after vhich the alcohol largely evaporates, vision will be obscured by the heavy glycol layer that remains.
To resolve this final problem,
certain amounts of water are included in the formulas.
The higher-quality
products vi11 have about 20%. while the economy types may have as much as 50 percent.
Table 36 presents a typical formulation.
Example Non-CFC Alternative Formulations
TABLE 35.
WOOD PANEL POLISH FORMULATIONS
FORMUTA (%l
INGREDIENTS D.C. 536 Fluid ( A n adnofunctional polydimethylsiloxane Dov Corning Corporation) copolymer
2.00
-
D.C. 200 Fluid (12,500 cstko) (Dimethylsiloxane polymer Dov Corning Corporation) Uitcamide 511
-
Witco Chemical Company
Isopar L and/or Isopar U Isopar K
-
-
-
Exxon Company
2.00 1.00
26.50 65.20
Exxon Company
Fragrance
0.05
Isopropanol (anhydrous)
0.25
Carbon Dioxide
3.00
Pressure (460-tmVacuum Crimp) bar at 21.1.C
7.40
TABLE 36.
WINDSHIELD DE-ICER FORMULATIONS
INGREDIENTS
FOWLA (%l
Methanol
-
Technical Grade
Propylene Glycol
-
Technical Grade
Deionized Water
54.00
18.00 25.00
Morpholine
0.10
Span 80 or Igepal CO-410 Non-ionics
0.05
Sodium Benzoate
0.05
Carbon Dioxide
2.80
267
268 Alternative Formulations and Packaging to Reduce Use of CFCs
The Igepal CO-410 ( R o b & Haas Co.) surface active agent is present in the formula in Table 36 because it improves the wetting activity of the formula, allowing it to penetrate more effectively into fissures and cracks in the ice, and then betveen the ice and the glass, for faster removal. PESTICIDE AEROSOL PRODUCTS Pesticides consist of insecticides, insect repellents, disinfectants, rodenticides, nematocides, herbicides, and a host of other products designed to reduce or elbinate pests in s i z e ranges extending from viruses to rats. All these products fall under the punriew of the EPA FIFRA if they are made or marketed in the U.S.
Other nations have similar regulations.
When pesticide
products are designed for use on the skin in the form of "outdoor lotions" that protect against solar radiation. poisonous plants, infections from scratches, and also contain insect repellant, the EPA still has control but may consult with other agencies, such as the FDA in this case, before giving pre-market clearance.
Information has been presented earlier on the dis-
infectant cleaner and disinfectant/deodorant spray, which are regulated by the EPA in the U.S.
. ides . Jnsect ic The insecticide was the first commercial aerosol product, used as early as 1944 for both military and domestic applications.
These early sprays were
true "aerosols" (unlike any of. today's products, except one type) and used 85 to 90% of CFC-12 to disperse the pyrethrin-containing concentrates.
The first
major segmentation of this product form came in 1953. with the introduction of the bug killer:
a coarse spray consisting of at least 75% kerosene-based
concentrate, used for surface wetting, instead of the usual space spray format.
By 1961. water-based space sprays came onto the market, and many
years later this technology was applied to the surface spray as well.
A l s o in
the early 1960s. a "whole-house insecticide." or "toral release indoor fogger" spray vas developed, typically using 85% CFC propellants. insect sprays were developed later in the 1960s.
Other specialty
They included the wasp and
hornet spray, pressurized with nitrogen or carbon dioxide, and which could
Example Non-CFC Alternative Formulations
269
throw a stream or streaming spray up to 6 meters. A number of pet-stock sprays were also introduced. Later. hormonal flea-control sprays, biocidal sprays, and other types were introduced. The space sprays are now essentially all water-based,since the other formulations were too costly and could not compete with the obvious economies offered by combinations of approximately 6 5 % water and 30% hydrocarbon propellant. The only exceptions are the total release indoor fogger (TRIF) and toxicant/propellant (T/P) sprays. The water-based space sprays can be closely compared with the air
freshener shown in Table 30. Formula A. By removing the perfume ingredient and replacing it vith a toxicant blend, the transition is complete. The water-based space sprays include the flying insect spray, house and garden spray, patio fogger. and a portion of the TRIF products. As a unit, they make up approximately 5 5 % of the insecticide aerosol volume. The TRIF spray made a difficult transition during 1978, when CFC
propellants were banned in the U.S.
Since it is designed to be latched open
and to discharge the entire contents of the can within two or three minutes, there is a greater inhalation and flammability hazard than is the case with most aerosols, which release only a few grams at a time. The flammability aspect related to
two
factors: the size of the container (and the number used
at one time), and the degree of product flammability. When problems have occurred, they have been caused by gross consumer misuse; for example, when two or more large cans have been set off in a relatively small area containing an ignition source such as the pilot light of a stove (range and oven), gasfired refrigerator or gas-fired hot water heater. Table 37 presents three forms of commercial formulations for these products. The relative flammability of the TRIF sprays can be assessed by using a
slight modification of the Department of Transportation (DOT) Closed Drum Test in.the U . S . The ZOO-liter drum is laid on its side, with the open end closed off vith a film of plastic. A candle is lit at the bottom and the spray is immediately introduced, using the test formula but
a
different valve more
270
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 37.
TOTAL RELEASE INSECT FOGGER FORMULAfIONS
INGREDIENTS Pyrethrum Extract
-
20%
Piperonyl Butoxide: Technical
FORMULA A
FORMULA B
FORMULA C
(%)
(%)
(%)
2.00
2.00
1.00
1.00
Emulsifiable Concentrate Petroleum Distillates
8.00
12.00
Methylene Chloride l.l,l-Trichloroethane
12.00 15.00
55.00
40.00
Deionized Water Propane A-108
7.00
50.00
30.00
Isobutane A-31
15.00
HCFC-22
15.00
35.00
271
Example Non-CFC Alternative Formulations
compatible vith the test procedure than the "latch open" type. The n&ber
of
grams of product sprayed into the drum until the Lower Explosive Limit (LEL) "poof" is reached and recorded.
From that figure, the number of cubic meters
that the dispenser can bring to the
LEL composition is readily calculated.
The usual insect repellent is used to keep users from being bitten or s t u n g by various flying insects.
The most c o m o n ingredient is N,N-Diethyl-m-
toluamide in concentrations of If to 30X of the total formula.
Sometimes
other repellents are added for protection against insects only partially repelled by the DEET active ingredient.
They include MGK Repellent 11 and ?fGK
Repellent 2 6 4 and are offered by the Mclaughlin. Gornley & King Company, of Minneapolis, PIN (U.S.). A typical formula is shown in Table 3 8 . Variations on Formula Type 26 include replacing the hydrocarbon propellant vith 4 . 5 % carbon dioxide, replacing the ethanol vith isopropanol, and removing the three MGK products, while increasing the level of DEET repellent to about 30 percent. The transfer efficiency from dispenser to skin or clothing is only about
55 to 65%. making other forms more attractive by comparison.
Lotions and
sticks are available, as vell as roll-on forms. PHARMACEUTICAL PRODUCTS These products are generally perceived as those that are inhaled, injected, or otherwise inserted into the body to mitigate or control medical problems such as migraine headaches, asthma, hemorrhoids, etc., or to provide a contraceptive function, such as vaginal contraceptive foam.
A few of these
products have already been covered in the foams area of this chapter.
The
primary one that remains is the metered dose inhalant drug (PIDID), which represents a U.S. market conservatively estimated at vell over 100,000,000 units per year and served by at least 28 brand-named products. As is common vith the rest of the aerosol industry, products are self-filled and also
272
Alternative Formulations and Packaging to Reduce Use of CFCs
I N S E m REPELLENT FORMULATIONS
TABLE 38.
FORMULA
INGREDIENTS
(%)
N,N-Diethyl-m-toluamida (95% A.I. min.)
20.0
HGK Repellent 11
2.0
MGK Repellent 326
1.5
MGK 264
1.5
S.D. Alcohol 40-2 (Anhydrous)
54.9
Fragrance
0.1 20.0
Propellant A 4 6 16 w t X propane and 84 wt X isobutane
TABLE 39. ~~
BETA-ADRENERGIC BRONCHODILATOR FORENLA ~
Ingredients
~
~~
~~
d10.5 g Can
~
Percentage (w/w)
Terbutaline Sulfate (Drug)
0.075
0 714
Sorbitan Trioleate (Excipient)
0.105
1.000
CFC-11
2.580
24.571
CFC-114
2.580
24.571
CFC-12
5.160
49.144
273
Example Non-CFC Alternative Formulations
contract filled. One or more self-fillers also contract fill for their competitors. At this time, all of these products use one or more of the
following propellants: CFC-11, CFC-12, and CFC-114. The volume of propellants used is approximately 1,900 kilotonnes (4,200,000pounds) in the U . S . alone. Table 39 shows a typical published formulation. Others are suggested in U.S. Patent literature and other documents.
Use of hydrocarbon propellants for some of these products is not satisfactory because of production problems related to flammability, the oily, stinging taste they have when inhaled nasally or orally, and their very low density (considered from the standpoint of drug precipitation rates during use). CFC-11 is slurried with the drug and one or more excipient materials, and this mixture is added to aluminum aerosol cans or bottles. They are then fitted with a ferrule-type meter-spray valve which is hermetically sealed to the container by a clinching or under-tucking operation. The CFC-12, sometimes mixed with CFC-114, is then introduced backwards through the valve. CFC-11, with a boiling point of about 23'C, is unmatched by any other nonflammable solvent of acceptable toxicology. Its replacement will necessarily depend on the availability of one or more of the "future alternative" HCFC and HFC propellants due to come on the market in 1992 or 1993. For the 90% of
PU)ID
products that use very finely divided microcrystal-
line drug particles (averaging from 3 to 5 microns), it is important to have a system of l o w solvency. Othewise. the larger particles will get still larger and the smaller ones (because of their higher surface energy) will get smaller until they vanish. This disturbance will severely limic the product effectiveness.
Even with the optimum particle size distribution, the body's
defenses are such that only 7 to 12% of the drug reaches the target areas. With the formation of larger particles in the container, this could drop below one percent.
io
274
Alternative Formulations and Packaging to Reduce Use of CFCs
The time frame needed for additional toxicological testing of the HFC and HCFC propellants, such as that being &ne
in the Program for Alternative
Fluorocarbon Toxicity Testing (PAFl'T)I. PAiTT 11, and PAFl'T I11 consortium tests sponsored by the chemical producers, is on. development. tions writing.
element of the new product
Another is actual formula and package development and specificaA third is the opening of each company's "New Drug Applica-
tion" to the FDA, reqwscing an "Amended New Drug Application" (ANDA). The entire documentation is reviewed in such procedurer. which typically take from
3 to 5 years to complete if there are
M problems.
One industry concern is
that the FDA MY not have sufficient staff to process approximately 27 concurrent ANDAS with anything like their usual timing.
These considerations
suggest that it would be to the advantage of chemical producers to cooperate in their efforts to have new products cleared by the FDA within the generally
planned transition period ending abouc 2000. The viability of new formulas depends on their solvency and toxicology. Preliminary results from PAFTT vi11 be released in September 1989.
Because of
the tincertainty about HCFC-123. three possible formulas are suggested here for consideration (see Table 40). The use of HCFC-124 is optional. since it merely serves co reduce the pressure slightly. The CFC-113 is used as an additive to the slightly flammable HCFC-1Glb to create a nonflammable blend for slurrying purposes.
If
the pharmaceutical firms and their fillers can handle a slightly flammable slurrying agent (pure HCFC-14lb). there will be no need to use the CFC-113 (or CFC-11). INDUSTRIAL AEROSOL PRODUCTS There are numerous aerosols used only in industrial or institutional applications. Two will be considered here:
a lubricant spray for phar-
maceutical pill- and tablet-making rotary molding machines, and an induscrial
275
Example Non-CFC Alternative Formulations
TABLE 40. --DOSE
INGREDIENTS
Z " T
DRUG FORHUIATIONS
FORHUTA A I%)
FORMTIA B
FORMULA C
(%)
(X)
Drug (as a microcrystalline suspension)
0.5
0.5
0.5
Excipient(o)
1.0
1.0
1.0
-
HCFC 123
13.5
CFC-113 (or CFC-11)
4.5
HCFC - 141b
9.0
HFC-134a HCFC-124
10.0 75.0
13.5
85.0
75.0
-
85.0
75.0 - 85.0
none
10.0
-
none
10.0
-
none
276
Alternative Formulations and Packaging to Reduce Use of CFCs
adhesive.
For the first application, the products must be nonflammable, and
leave only a Food Grade [Generally Recognized as Safe (GUS)-Listed] residue on surfaces to be contacted by the pharmaceutical pill or tablet. A current formulation is shown below:
Innredients
txy
Lecithin (Soy Bean source)
2.0
Sorbitan Trioleate
0.5
Ethanol (Anhydrous)
2.5
CFC-113 (Especially purified)
70.0
CFC - 12
25.0
An intermediate step could replace the CFC-12 vith a mixture of
LO parts HCFC-
142b and 20 parts HCFC-22, reducing the CFC-113 to 65 parts in the process. This vould reduce the CFC content by 32 percent. When the future alternative propellants become available, the formulations shown in Table 61 could be considered, Substantial testing of these prototype formulas in Table 41 vould be required as a prerequisite to commercial use. Adhesive SDray A typical industrial product is the adhesive used to coat automotive gaskets before setting them in place on engine blocks or other equipment. Aerosol products have a substantial niche in this market area. A typical formulation is illustrated in Table 42. The product is sprayed onto the gasket while it lies on a waxed paper or ocher suitable substrate. After a minute or so, much of the methylene
chloride will have evaporated, bringing out the stickiness of the resins. After another five minutes. the gasket is ready to be applied to the engine block or other item.
Example Non-CFC Alternative Formulations
TABLE 41.
ROTARY TABLET W C H I N E DIE LUBRICANT FORMULATIONS
FORMULA A
INGREDIENTS
FORMlLA 8 '
Lecithin (Soy h a n source)
2.0
2.0
Sorbitan Trioleate
0.5
0.5
Ethanol (Anhydrous)
2.5
2.5
77.0
HCFC-123 HCFC-14lb
55.0
HCFC - 22
HCFC 124
30.0
18.0
10.0
'Formula B could replace Formula A if HCFC-123 does not become commercially available. TABLE 42. GASKET ADHESIVE !?ORHUIATION
INGREDIENTS
FORHULA
~
Isopropanol
LO
Resin 80-1211.
5
Stabilite Ester Number 3b
5
Methylene Chloride
50
Xylenes
10
Propellant Blend A - 7 0
20
Hade by the National Starch and Chemical Company.
%de
by Hercules, Inc.
277
Section II
Alternative Aerosol Dispensing Systems
I1 of
as
are But
1. Introduction imposing number of packaging alternatives to the standard aerosol dispenser are available.
Several use aerosol containers, but segregate the
propellant gas, and employ a finger-pump, trigger-pump, hand-operated piston action, a metal spring, screw device, or other mechanism to dispense the product or form tlie propellant gas within the container as required.
Others
take the form of rather specialized, non-aerosol containers designed to enable the usar to create air pressure or product pressure, or to operate screw-on finger-pump or trigger-pump metering valves.
The pump-sprays, in all their
diverse forms, represent the most widely used alternative.
Such packaging
options as stick applicators, pads, etc. offer alternatives to the aerosol system but do not provide sprays; these will only be briefly described. A substantial number of aerosol alternatives will be described in Part I1 of this report, beginning with those that are most similar to conventional
aerosols--and that may even be considered aerosols by various persons and authorities--and continuing with alternate packaging forms that bear no resemblance to aerosol products.
The term "aerosol" vas used by the scientific community at least as far back as 1838 to describe dispersions of liquids in a gaseous medium, such as fog, mists, and clouds, where the particles were true colloids, having diameters of approximately 0.005 to 0.200 microns ( p ) .
Particles of this
magnitude were able to remain air-borne indefinitely. The smallest particles are the same size as many larger molecules, such as starches, proteins, and rubbers, and this part of the definition has not changed over the years.
279
But
280 Alternative Formulations and Packaging to Reduce Use of CFCs
the high end of the size range o r i g i n a l l y defined a s the l i m i t of microscopic v i s i b i l i t y , has changed g r e a t l y .
The s o - c a l l e d "coarse aerosol" ( t o the
p h y s i c i s t ) now includes dispersions of p a r t i c l e s ranging from 0 . 2 t o about 20 microna ( p ) .
Since the p a r t i c l e s i z e d i s t r i b u t i o n of comnercial aerosol
sprays is generally in t h e 1 t o 100 micron ( p ) range, a t l e a s t some of the sprays meet the expanded classical dofinition.
Some e a r l y d e f i n i t i o n s of anroaol products were based on p a r t i c l e s i z e . For example. around 1969, the U.S. Department of Agriculture (USDA) designated t h a t the 'true aeroaol" i n a e c t i c i d e waa one in which a t least 808 of the p a r t i c l e s had a mean diameter of 30 microns ( p ) o r l a s s , and i n which no p a r t i c l e could have a mean diameter g r e a t e r than 50 microns ( p ) .
To meet
these requiremants, chemists had t o design formulas with 80 t o 85% o r more of propellant.
The r a t i o n a l e w a s that t h e spray p a r t i c l e s had t o be very s m a l l
t o remain airborne f o r tvo minutes t o tvo hours t o c o n t r o l f l y i n g i n s e c t s . The products soon became known as space sprays. A t about t h e same time, t h e USDA introduced the "pressurized spray"
concept f o r insecticides chat were'slightly more coarse.
The mass median
diameter of a11 p a r t i c l e s had t o be about 25p. and some could be above SOU Because t h e l a r g e r p a r t i c l e s f e l l t o the f l o o r in less than one minute, marketers had t o use l a b e l d i r e c t i o n s t h a t advised the user t o spray an a d d i t i o n a l 2 5 - 5 0 8 more product i n t o the a i r space of rooms. F i n a l l y , about 1951, the " r e s i d u a l spray" i n s e c t i c i d e w a s defined. E s s e n t i a l l y a l l p a r t i c l e s had t o be l a r g e r than 50p, so t h a t such t o x i c a n t s as Chlordane, Strobane and DDVP (dichlorphos) vould not be inhaled t o any significant extent.
These were used only f o r spraying baseboards, doorway
sills, wasp-nests, and o t h e r inanimate surfaces. The piston-pump i n s e c t i c i d e sprayer could dispense d i s p e r s i o n s of p a r t i c l e s about 2Sp i n s i z e with deodorized kerosene formulacions and those 20p i n s i z e with the more flammable athanol and isopropanol compositions.
finger-spray and ( l a t e r ) t r i g g e r - s p r a y insecticides generally provided d i s t r i b u t i o n s of p a r t i c l e s in the 30 t o 8Op range.
Consequently, much more
The
Introduction 281
had to be used for the control of flying insects, and the range of action was also much Less than that of aerosol dispensers.
The confuaion between "aerosol" (the colloid sol) and "aerosol" (the dispenser) has existed since the aerosol industry w a s born in 1943.
In an
intern81 report, the Acdomic Press Inc. publishing house M n t i O M d that more copies of one of their M V textbooks 1 -(
S
w
, C.N. Davies
-
Editor,
1966) had gone to recipients in the aerosol packaging industry than to the intended audience of physicists. physical chemists, and meteorologists, mainly because of the lack of contents identification in
SOP.
advertising and
The industry made an attempt to rename itself as the
proPotiona1 materials.
"Self-pressurized Dispenser Division" of the Chemical Specialties Manufacturers Association. Inc. (CSHA) but the proposal vas defeated.
Today,
the vords "aerosol" and 'self-pressurized" product are used interchangeably. For the purposes of interstate transportation, the U.S. Interstate Cotmerce Comission (XCC), n w a branch of the Department of Transportation
(DOT). defined the aerosol package in 1948 as follows: "A sealed package containing base product ingredienu, fn which one
or more propellants is dissolved or dispersed. and fitted with a dispensing valve." Despite the fact that many self-pressurized products thought of as aerosols do not strictly meet this definition, nearly a11 are currently shipped under Section ORPI-D of the tariff.
(The definition has been modified
slightly over the years.) Other definitions are listed below without special comwent: CSPIA Definition:
'A pressurized sealed container with liquified or
compressed gases so that the product is self-dispensing," FDA Definition:
"A package consisting of a container and valve, into
which is added a base product and propellant, causing the dispenser to be
282 Alternative Formulations and Packaging to Reduce Use of CFCs
under pressure. and able to discharge the product as a spray, foam, liquid, gel, or other form."
H.R. Shepherd (Book) Definition, 1960:
A '
container whose contents are
expelled through an opened valve by means of tha internal pressure of the materials contained therein.' P.A. Sanders (Book) Definition, 1979:
(Also used by CSMA)
"A self-
contained sprayable product in vhich the expelling force is supplied by a liquified gas." National Paints and Coatings Association (NPCA) Definition:
A '
self-
contained package which contains the product and the propellant necessary for the expulsion of the former." British Aerosol hnufacturers Association, Ltd. ( W ) .1971:
'As
integral ready-to-use package incorporating a valve and product which is dispensed by prestored pressure in a controlled manner when the valve is operated.' Most of these definitions were created by one person, then approved by a committee or by a brief committee action.
Some are ill-conceived or outdated
and either do not cover all aerosols, or cover products not commonly denoted as aerosols.
In a recent inquiry to the DOT, a product consisting of a
mixture of Halon-1301/1211 ( 2 0 : 8 0 ) was finally judged to be a non-aerosol and denied the standard aerosol O M - D exemptions because it contained no base product ingredients.
Two materials other than propellant had to be present to
be designated an aerosol.
The prospective marketer finally added a drop of
kerosene (a mixture of ingredients) to 13 Av.02. (369 g) of the Halon blend, and is now selling the product. At a recent industry meeting, representatives from the Metal Box Division
(CMB) in England stated that they had persuaded British Aerosol Manufacturers Association (BAMA) and the F U (Federation of European Aerosol Associations) in Western Europe that self-pressurized products placed in their "Bi-Can," a
Introduction
283
compartmented can containing an inner plastic bag for the base product, should This would give them preferred treatment by the
not be considered aerosols.
folloving transportation authorities:
0
ADR
European Agreement for the International Carriage of Dangerous
Good. by Road.
RID International Convention Concerning the Carriage of Goods by Rail (Borne 1961; Annex 1).
0
U T A International Air Transport Aasociation (Restricted Articles
Board).
0
INCO International Plaritime Consultative Organization (United Nations).
They asked for industry support in the U.S.
No action was taken.
Another definition of an aerosol product that has often been published is as follows: *A hermetically sealed metal. glass or plastic container, fitted or able to be fitted with a valve, and containing a base product and/or a liquified and/or high-pressure propellant, able to dispense the contents in a controlled manner as either a spray, foam, stream, gel. paste, lotion, gas. powder or combination.” In the U.S., for the purpose of interstate transportation, aerosols are limited to 50 cubic inches (819.35 mL) in metal cans, or to 4 fluid ounces (118.28 mL) in non-metallic containers.
The United Nations recommendation is
1000 mL for all products, and this is generally followed in Europe.
In Japan
and other countries, the capacity limit is 1400 nL. although other restrictions apply.
A few countries permit “aerosols” up to 20 liters in
capacity if made of steel.
In the U.S., steel cylinders up to 40 liters in
capacity are used for insecticide sprays, egg treating mineral oils, and other
284
Alternative Formulations and Packaging to Reduce Use of CFCs
specialized applications. They are not considered aerosols.
In some beauty
shops, hairspray concentrates are dispensed from pressure tanks maintained at about 100 psig (7.04 bar) compressed air pressure at ambient temperature. The operator uses a thin hose urd breakup nozzle for product applications. These
products are also not considered to be aerosols.
2. Description of Aerosol Packaging Alternatives BAG-IN-CAN TYPES
The Seuro C a
I n 1954, Croce p a t e n t e d a perfume s p r a y i n which t h e perfume c o n c e n t r a t e and t h e p r o p e l l a n t w e r e c o n t a i n e d i n s e p a r a t e r e s e r v o i r s ( U . S . P a t e n t
2,689,150). And i n 1955. t h e Metal Box Company, Ltd. v a s g r a n t e d a B r i t i s h p a t e n t f o r a d e v i c e t h a t would permit the d i s p e n s i n g o f flowable p r o d u c t s where t h e product and p r o p e l l a n t were k e p t s e p a r a t e from one a n o t h e r ( B r i t . P a t e n t 740,635).
I n 1958, t h e C o n t i n e n t a l Can Company, I n c . f o r m a l l y i n t r o -
duced t h e i r Sepro Can. which c o n t a i n e d a n accordion-shaped polyethylene p l a s t i c a l l o y bag i n s i d e a s p e c i a l l y designed a e r o s o l can measuring 1 1/8" by
6 1/8" (53 x 156 mm).
The u n i t v a s f i l l e d by f i r s t adding as much c o n c e n t r a t e
as p o s s i b l e t o t h e bag, t h e n s e a l i n g the top with a one-inch a e r o s o l valve.
A f t e r t h a t , p r o p e l l a n t gas vas i n j e c t e d through a small h o l e i n t h e base s e c t i o n o f t h e can and t h e h o l e v a s plugged with a s h o r t l e n g t h o f rubber cording.
Only a f e u grams o f p r o p e l l a n t were needed t o d i s c h a r g e from 1 7 5 t o
250 grams of product ( a c c o r d i n g t o i t s d e n s i t y ) , si'nce t h e two were k e p t s e p a r a t e by t h e bag.
Also. t h e p r o p e l l a n t would never be d i s c h a r g e d d u r i n g
t h e l i f e t i m e of t h e can. b u t would remain i n s i d e u n t i l t h e empty u n i t w a s crushed, shredded, i n c i n e r a t e d o r r u s t e d through i n a dump s i t e , e x c e p t f o r an i n f i n i t e s i m a l amount t h a t might seep through t h e plugged and double seam can s e a l s and escape i n t o t h e atmosphere. C r o s s - s e c t i o n a l views of t h e Sepro Can. a mechanized o r pneumatic squeeze cube. a r e s h o w i n Figure 2 .
285
286
Alternative Formulations and Packaging to Reduce Use of CFCs
I
l
/ SEPRO BAG
\
e PROPELLANT CHAMBER Figure 2 .
CHARGl NG VALVE The Sepro C a n
CAN
BODY
Description of Aerosol Packaging Alternatives
The Sepro Can. from the term "Separate =duct
and Propellant," was
designed to permit gas-free dispensing and the dispensing of viscous produ that had a positive yield point.
287
S
It was hoped that this package would
facilitate the growth of the aerosol business by allowing a new range of products to be packaged under pressure. The standard aerosol cannot dispense products with viscosities much
beyond 350.000 cps.. since such chemicals and formulas usually have a positive vield point, or, in other words, exhibit shape retention. For example, if a toothpaste is filled into an ordinary aerosol can and placed under 100 psig (7.04bar) of nitrogen pressure, an appropriate valve and spout will dispense the produce very nicely, although some slight expansion of the extruded paste may occur as dissolved nitrogen gas slowly forms almost invisible foam bubbles in the product.
(This is too insignificant a feature to be observed by the
casual user.) Within the aerosol can, however, each actuation causes a further cavitation of the initially flat toothpaste surface. At a certain stage the crossThe cavitation area will deepen with each
section looks as shown in Figure 3 .
additional actuation, until it reaches the bottom of the dip tube. At that point the nitrogen gas will exit in a fraction of a second, and the remaining product cannot be dispensed. Toothpastes have been prepared without positive yield points. so that the cavity left after each actuation will slowly heal--or flatten out. However, they tend to drip off the toothbrush to some extent and will also leak out of the valve spout orifice onto the top of the container. Some of the nitrogen propelled (nitrosol) toothpastes of the early 1960s had spout plugs, connected to the spout by a fairly thin polyethylene filament. They were designed to be applied to the spout orifice after actuation, to prevent dripping. Sometimes the pressure created by releasing nitrogen gas caused them to pop out. One major marketer (Colgate) kept such a product on the market for about twelve years, selling 300,000 cans a year to persons who liked the dispensing system.
288
Alternative Formulations and Packaging to Reduce Use of CFCs
Figure 3 .
Ordinary Aerosol Dispenser with Toorhpaste. (About 15 percent Dispensed)
Description of Aerosol Packaging Alternatives
289
But a slowly diminishing business of this small magnitude was unappealing to Colgace and they finally dropped the item.
In the mid-l960s, the Continental Can Company developed and vigorously promoted to marketers the folloving four Sepro Can sizes:
202 X 214m 202 X 006mm
(3-fluid ounce capacity)
202 X 509mm 211 X 6041m
(7-fluid ounce capacity)
*
(5-fluid ounce capacity) (16-fluid ounce capacity)*
Never produced commercially.
A major detraction was the need for marketers to spend about twice as much for Sepro Cans as for ordinary aerosol cans, as well as to install specialized "gasser-plugger" and other equipment on their packaging lines. also had a few quality problems.
The package
Except for "Edge." a patented gel-type
shaving cream developed by S.C. Johnson C Son, Inc. in 1969, no major uses developed. The evolution of the plugging technology went through several stages. A: first, a gasser-plugger would inject a liquified or non-liquified gas into che filled can (1 to 7 g) and then ram the end of a 5/32" (0-mm)diameter lubricated neoprene cord or rod into the 1/8" (3.2-mm) diameter hole in the center of the can base.
After insertion, the machine would cut the rubber cord off
from the rest of the reel. These early machines, required to perform three fairly complex operations in a sealed area, were production nightmares and generally the rate-limiting factor in manufacturing operations.
Much later, engineering improvements were
made to increase the viability of this sealing approach. Then Continencal Can Company announced an improvement known as the Nicholson Model 2 plug valve.
It consisted of a solid rubber billet or plug,
partly splined on ehe side wall, which was designed to fit part-way into the
290 Alternative Formulations and Packaging to Reduce Use of CFCs
can hole during manufacture.
In the filling operation, propellant gas was
introduced through the splined channels, after which a small ram was used to force the plug fully into the hole, making an hermetic seal.
This plug, with
only slight residual modifications, is still in use today. The early plastic bag designs were highly pleated or accordion-walled, and this caused problems when filling viscous concentrates such as pastes and gels.
The Continental Can Company purchased a single-head and twin-head Elgin
spin-filler, useful for filling these products, which they loaned to certain marketers and larger contract fillers to help in product development work. Larger machines, such as six- and twelve-head Elgins, were available.
A
very
large Consolidated Equipment Company eighteen-head filler was modified for by S.C. Johnson 6 Son, Inc. as a spin filler.
use
Finally, the Pfaudler Mfg.
Company later introduced a six- and twelve-head spin filler. The Consolidated and Pfaudler machines have a pressurized bowl option, for containing any vapors from shaving gels that contained isopentane [(CH,),CH-CH,-CH,]
or other
flammable or excessively volatile concentrates. Every concentrate was found to have an optimum spin-filling rate, generally in the range of 400 to 1200 r p m .
Below 400 r p m , the centrifugal
force was often insufficient to effectively drive the concentrate into the pleated areas, causing unwanted air pockets to form and survive. Over 1200 r p m , concentrate vortexing would exceed gravity and product would be spun
upward and out of the container. During 1971. the products shown in Table 43 were being packaged in the Sepro Can dispenser. The labeled formulas for the "Edge," "Rise." and "Foamy" gel shave creams are presented in Table 44. In accordance with Food 6 Drug Adninistracion (FDA) regulations, these cosmetic products must list their ingredients in
order of decreasing percentages; those present in concentrations of less chan one percent may be placed in any order.
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of Aerosol Packaging Alternatives
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291
292 Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE U. CTFA lABEL INGREDIENT LISTINGS FOR THE THREE GEL-TYPE SHAVE CREAMS Edge Ultra G e l
Rise Super Gel
Foamy Shaving Gel
Water
Water
Water
Palmitic Acid
Palmitic Acid
Stearic Acid
Triethanolamine
PEG-150
Oleth-20'
Pentaneb
Diethanolamine
Triethanolamine
Sorbitol
Myristic Acid
Isopentane
Fatty Acid Esters
Isopentaneb
Lauramide DFA
Isobutane
SD Alcohol 40
Isobutane
Cellulose Polymer
Acetylated Lanolin Alcohol
Peanut Oil'
FD&C Yellow No. 10
Mineral Oil' Isobutane
F D K
Blue No. 1
Hydroxyethylcellulose Fragrance Fragrance
Fragrance PEG-90M
Coco-triglyceride' FD&C Blue No.1 Menthol FD&C Blue No. 1 D&C Yellow No. 10 'Lubricants, used to seal in moisture. bThe pentane and isopentane foamants are used in concentrations of about 1.4%
of the formula.
Description of Aerosol Packaging Alternatives
The three formulas are quite similar.
293
Each has the di- or triethanol-
amine ester of C1, to CI8 fatty acids as the primary surfactant.
Sodium and
potassium fatty acid soaps are absent, although they are always seen in conventional shave creams.
Cellulose, hydroxyethylcellulose, or high-
molecular weight polyethylene glycols are used to achieve the gel structure. Most particularly, approximately 1.5% of low-pressure propellants are incorporated into the g e l structure, so that the extruded gel can be "magically" converted to a heavy foam on contact with the warm surface of the palm or fingers or if touched and manipulated slightly. CFC-113 (CCl,F*CClF,), to use isopentane.
The original "propellant" was
but after the FDA ban in 1978 the formula was converted Later, for a faster and more reliable transition, mixtures
of n.pentane/isobutane (80:20) and isopentane/isobutane (90:lO) became popular. Around 1973, a regular shave cream called "Pour H o m e " (For Men) was marketed in a Sepro Can.
The shave cream contained 3.25% of Propellant A - 4 6
(which is 15 wt X propane and 85 wt X isobutane), and the "exospace" (the volume outside the bag but inside the can) contained Propellant A-60 (32 wt X propane and 68 wt % isobutane). With a pressure ranging from 16 to 29 psi higher than the product at 70'F
(1.1 to 2.0 bar at 21'C).
rhe product was
extruded at a reasonable flow race. and since no propellant could ever escape from the concentrate into an expanding head space, as happens with all regular aerosols as they are used up, the foam density and overrun remained exactly constant for "Pour H o m e " during its service life.
After two years, the
company was unable to obtain Sepro Cans to continue its operations and the product was terminated. At present, the Continental Can Division of U.S. Can Company, Inc. is the only U.S. producer of this type of container. 52MM units a year.
They have a capacity o f 50 to
The cans themselves are produced only on the firm's "Z-bar
TFS Conoweld I" line at their fabrication/assembly can-making plant near
Racine, VI.
The line has a capacity of about 53 million units a year on a
ten-shift-per-veekbasis, and sub-assembly units, such as the pierced base with loosely fitted plug, can be produced at only a slightly greater rate.
294 Alternative Formulations and Packaging to Reduce Use of CFCs
The plastic bottle or "bag," as it is generally called, is made at the company's Burlington, UZ: facility. using three "wheels" or individual production lines, each having a capacity of 17.5 million units a year on a threeshift, five-days-per-week basis.
Originally, the bags were made of either
polyethylene (XBPE) or of a particular 'Conalloy" plastic alloy. m e has nov been elimfruted.
The former
The current Corulloy bag consists of low-
density polyethylene. nylon, and a proprietary binding agent produced by W o n t that makes the two plastics more compatible.
The Conalloy bags mold
better than LDPE types and have been used continuously since 1968. While the discontinued LDPE had better resistance to moisture permeation than Conalloy, the latter is superior as a hydrocarbon propellant barrier. This characteristic became critical when Edge shave cream had to be reformulated in 1978 to eliminate the internal CFC-113 foamant and the external CFC-
12/114 (60:80) blend (CCl2FJCC1F2*CC1F2) in favor of isopencane and isobutane/propane (87:13), respectively.
When hydrocarbon Edge formulas were
packed in Sepro Cans with LDPE bags, traces of immediate foaming were seen in gels dispensed after as little as eight months of room temperature storage and five months of 100'F
(38.C)
storage.
In contrast, when Conalloy bags were
used, technicians could.not detect instant aeration until after 14 to 16 months of storage and the permeability did not escalate to a consumer problem until the product had been stored 20 to 24 months at 70'F
(21°C).
During late 1981. a 100% nylon bag became commercially available. a stronger, tougher bag than the Conalloy type.
It w a s
It vas pre-form or parison
molded at a substantially higher temperature than the Conalloy type, making it possible to fill Sepro Cans with very hot products, and even t o sterilize them in an autoclave to the usual 252'F below 122'F
(50'C).
(122.2.C)
if desired.
After cooling to
the Sepro Can may then be gassed and the bottom sealed.
Advantages of the nylon bag are that much less plastic is needed, and the critical "T-tab" area at the bottom of the bag knits cogether very effectively and reliably, like the earlier LDPE bags but unlike the Conalloy type. or thin spots have been a continuing problem of the Conalloy bags.
Voids
Description of Aerosol Packaging Alternatives
295
During 1983, the "Lamicon" bag vas developed for Sepro Cans, using a Japanese process for the pre-form or parison blow-molding of multi-layered plastics.
The wall of the Lamicon bag is composed of LDPE/adhesive/EVAc/
adhesive/LDPE, vherein the EVAc stands for ethyl vinyl acetate polymer. provides an excellent barrier for oxygen and other gases.
EVAc
It has a good
record in food bottles, and Sepro Can tests show the same good performance. It is also an excellent hydrocarbon gas and liquified gas barrier. The Conalloy, nylon, and Lamicon bags can be effectively used with a great variety of products, but there are reasonable limitations, as with all packaging systems.
0
Some are listed below:
There may be problems with products whose viscosities are over 9 5 , 0 0 0 cps. (0.g.. very thick molasses) at the discharge tempera-
ture : Nylon will take up to about 350.000 cps. but transport rate through even very large orifice valves may be slov. Clayton and Super-Whip valves have "huge" orifices available, if inverted applications are acceptable. Special Precision, Bestpak, and Beard valves are sometimes useful. Increasing the propellant pressure outside the bag is useful, up to the practical limit of 70 psig (4.9 bar) at 70°F (21'C) In contrast, regular aerosols can only handle products with viscosities up to 2.000 cps at room temperature. Products that exhibit pressure-induced syneresis:
--
The application of hydraulic or pneumatic pressure to some
liquid-in-solid products will cause the liquid to be partially squeezed out of the matrix.
An example is peanut butter, where
296 Alternative Formulations and Packaging to Reduce Use of CFCs
the peanut o i l can be synerized out of the mixture, leaving a s u b s t a n t i a l l y s t i f f e r bottom l a y e r .
I n i t i a l experiments have
shown t h a t regrinding the peanut fragments w i l l reduce o r resolve t h e problem.
--
When ordinary peanut b u t t e r s a r e packaged i n Sepro Cans (using nylon bags) t h e u n i t s operate w e l l f o r t h e f i r s t few days, bur then d e l i v e r increasing amounts of peanut o i l . and a f t e r a l l t h i s is discharged, the remaining p a s t e is too s t i f f t o extrude.
Products t h a t a r e highly lubricous:
--
A s a l a d o i l product can cause the rubber grommet and s e a l of
the Clayton valve t o force out of the valve cup and f l y across a room.
--
This does not occur with stem-type valves.
A s i l i c o n e product managed t o permeate the bag i n micro-gram
amounts over many months, ultimately l u b r i c a t i n g a n i t r i l e rubber plug t o the degree t h a t i t popped out of the hole i n the base s e c t i o n .
Sepro Can storage a t 122°F (50'C) exacerbated
the problem. Products t h a t a r e a c i d i c :
--
Although vinegar ( a c e t i c a c i d based) products can be placed i n Sepro Can bags and used i n connection
with valve
CUPS
t h a t are
laminated v i t h polypropylene o r l i n e d with nylon, so t h a t no d i r e c t metal contact is possible, the contained a c e t i c a c i d (CH,*CO,H) can permeate through Conalloy and nylon bags and a t t a c k the t i n - f r e e s t e e l (TFS) Conoweld I can s u r f a c e s . Reformulation with malic o r c i t r i c a c i d s is useful i n some instances. since these do not permeate t o a s i g n i f i c a n t extenc.
Description of Aerosol Packaging Alternatives
0
297
Clear gel products that may have long shelf lives before use:
--
Hydrocarbon propellants are able to permeate Conalloy and nylon bags sufficiently to render gel shave cream products substandard after 20 to 24 months at room temperature.
The
problem seems to be strongly reduced if Lamicon bags are used.
0
Certain solvents are capable of bag degradation.
A solution that
included 64% turpentine slowly turned an LDPE bag into a semiviscous mass, and one with a vegetable oil did the same at 122'F (5O'C).
Diethyl ether, an 8% sodium hydroxide oven cleaner base,
boiled linseed oil. and cyclohexanol all act to slowly degrade nylons.
0
The use of alternate bags is sometimes an answer.
Products that must be hot filled:
--
None of the available systems will fail when concentrates are filled up to about 145'F
(63'C)
and propellant is introduced at
any time thereafter.
-
If concentrates are filled between 145 and 160'F
(63 and 71°C).
the propellant must be limited to isobutane, nbutane or their mixtures. or over-pressurization will occur.
Exception:
Higher-pressure propellants may be used if the hot concentratds are given time to cool to 145'F
--
Above 176'F
(8O'C)
(63.C)
or less.
the Conalloy and Lamicon bags may distort o r
have a better chance of dissolving in certain concentrates. Nylon bags should be used in such cases, since they can withstand temperatures up to 280'F
(138.C) vith most con-
centrates. Depending on bag size, bag composition, and, to a small extent. the product itself. Sepro Cans will dispense from 94 to 97% of the contents within the bag.
The propellant outside the bag is not dispensed.
In the U . S . , only
298 Alternative Formulations and Packaging to Reduce Use of CFCs
the dispensable amount of the product may be listed as the net weight.
As a
rule, the Sepro Can operates vith far less propellant than any standard aerosol product. Considering hair sprays, most conventional (single compartment) aerosols use from 22 to 35% hydrocarbon propellant, or about 35% dimethyl ether propellanc in the formulation.
For a corresponding Sepro Can of the 202 x 509
size, the amount of exospace propellant vould be about 2% of the weight of the concentrate.
Some coarsening of the product would result from this transi-
tion, since the usual "micro-explosive" effect of the propellant evaporation would be absent. The Sepro Can may be operated in any position, since the bag is always liquid filled.
In fact, during the concentrate filling step, care should be
taken to fill the bag to the maximum, while allowing room for the valve mounting cup insertion into the throat without overflow.
Small air pockets,
when expelled, may sometimes make a "splat" noise and cause some products to spatter.
Fairly costly inverted or "spray-anyway" valve options are not
required for Sepro Cans.
As the product is used up, the bag collapses upward in a controlled way because of the circumferential pleat design. No bag pinch-off will take place.
The latest pleat profile consists of gently rounded "V"-shaped
indentations between 5/16" (E-mm)-high vertical wall sections. the earlier, more sharply indented "!!"-shaped
Compared with
pleats, the new bags provide a
more controlled collapse pattern, increased bag capacity and a generally increased ease of filling viscous concentrates.
A
minor objection is chat ihe
Sepro Cans become increasingly top-heavy during use, as the bag collapses upward.
This is most noticeable with dense concentrates such as toothpastes.
A special one-inch dome section is required for Sepro Cans, with the opening enlarged from the usual 1.000 2 0.004" to 1.021 t 0.003" (25.40 5 0.10 mm to 25.93 2 0.07 mm).
This recognizes the approximately 0.10" ( 0 . 2 5 - m m )
thickness of the Conalloy and Lamicon bags in that area, so that with bags in place the net opening will be correct for the standard one-inch valve cups.
Description of Aerosol Packaging Alternatives
299
In the case of the thinner nylon bags, an intermediate can opening is required. The Sepro Can may be closed with any standard valve cup and standard crimping tools; e.g., collet and mandrel (plunger). (27.18 f 0.07-mm) crimping diameters may be used.
Standard 1.070 5 0.003"
However, the crimp depth
nust be made larger, to account for the bag thicknesses at the crown and at the point of hard contact. in the crimping process.)
(Actually. both are crushed to thinner dimensions Favored crimp depths are in the 0.180 5 0.004"
(4.57 f 0.10-m) range. The can uses a regular necked-in 201-diameter bottom, uniquely pierced with a 1/8" ( 3 . 1 8 - m ) hole in the center and having an upward lip or flange projection into the can.
The Nicholson Model 2 . two-stage charging valve is
supplied by the can-maker and inserted to the first stage (loose) position in the hole.
The filler introduces the propellant through the valve's ports,
filling the area between bag and can.
Depressing the valve to its second
position with a ram seals the propellant inside. The fit between plug and can base is very efficient.
The leakage rate is
always less than 0.50 g per year, and often less than 0.05 g per year at room temperatures. Should severe over-pressurization take place because of heating, the plug will remain in place even if the can eventually ruptures. Sepro Cans are equivalent to other aerosol cans in terms of pressure resistance.
They can be hot-tanked at temperatures up to 170'F
propellant is isobutane.
(77'C)
if the
During hot tanking, the contents of the bag do n o t
significantly warm up, since the gas-filled exospace and plastic barrier are effective insulators.
However, because of the pressure exerted on the can by
the propellant in the exospace. all DOT regulations are satisfied. There is a wide choice of propellants in the U.S. isobutane or lower-pressure blends of propane/isobutane. act to soften the bags.
The usual ones are Dimethyl ether might
For two reasons, the high-pressure compressed gases,
300 Alternative Formulations and Packaging to Reduce Use of CFCs
carbon dioxide (CO,) nitrous oxide f N , O ) . nitrogen (N2). and ethane (CH,.CH,) are not appropriate: There is no reserve against slow leakage. (In the case of liquified propellants, a small liquid pool is present to replace lost propellant gas by evaporation); Pressures will diminish substantially as the bag slowly collapses during product use because the absolute pressure varies inversely with headspace or outage space volume. This can be shown by the following example:
_-
The volume of the exospace is 40 mL.
The initial pressure of
carbon dioxide is 115 psig. After 80 mL of product has been expelled (about 1/3 of the total). what is the remaining pressure?
- 130 psi-absolute 'Final - 'Initial x'Final/sInitial) psiInitial Pressure is 115 + 15
43.3
absolute Final Gauge Pressure
-
43.3
-
15.0
-
2 8 . 3 psig
The example shows that such propellants are unable to dispense the entire contents of Sepro Cans. Practical propellants for Sepro Can gassing are the hydrocarbons: nbutane, isobutane. and propane, or their blends. Establishments unable to safely fill hydrocarbon propellants may wish to use such blends as HCFC22/142b (40:60)for non-food items. As product viscosity increases. higherpressure [up to 70 psig at 70'F (4.9 bar at 2l0C)] blends of butanes/ propane may be preferred. The action of Clayton, Super-Whip. and other stalktype toggle valves can be stiffer at these higher pressures because of resistance factors.
Descriptionof Aerosol Packaging Alternatives 301
Sepro Cans are presently being made on only one production line in the
U.S. It has a speed of 240 units per minute and averages 110.000 units per shift. It is scheduled to run at a maximum of three shifts one day, two the next, three the third, and so forth, allowing for maintenance during the third shift on every second work day. Considering 200 days of operation a year, the output is 52,000,000units a year. Changeovers, from the standard 202 x 509 size to the 202 x 314 sample size, for example, are very costly to the supplier, requiring about 5 days of downtime for both the can-making and bottle-making plants, and a similar period to change back.
It would take,anorder of 5 to 100 million cans for
this to be feasible, and the can-maker has so far sold all sample cans to marketers at about twice the usual discounted prices. Quality problems that caused S.C. Johnson h Son, Inc. to reject as many as 30% of all "Edge" Sepro Can pallet loads during 1980 and 1981 were reduced
to a 0.28% reject rate in 1984 and to a 0.21% reject rate in 1987. The quality problems included the following:
0
Welding faults--lackof integrity due to the presence of cold weld areas on the can side seam.
0
Crimp problems--lackof integrity due to offset parting lines on the bag neck lying against the curl of the can. Since the bag-to-curl interface has co seal pure hydrocarbon gas. with no solvent action to soften or swell the plastic--tohelp create a more effective barrier--offsettingis a very serious consideration. The offset distance is tightly controlled and measured frequently during bag production.
0
Incompletely molded rubber grommet. Grommets are made on a complex, 98-cavity mold, and sometimes the rubber fails to fill the entire volume of each cavity.
302 Alternative Formulations and Packaging to Reduce Use of CFCs
0
Weak tail tab on the base of the bags.
Presently a thicker (and
thus stronger) knit line is used, together with a recessed construc-
tion.
0
Top seam problems.
The top double seam cannot be tested during can
production for hermetic integrity, becauae of the bag.
For example,
welded end cracking has caused problem in this area. Despite the manufacturing complexities of the overall Sepro Can package, the Continental Can Division currently feels that it produces a very highquality item, partly because of the insistence on quality by customers. The 1989 pricing of Sepro Cans of standard size is as follows:
JOO.000 Unitg
500.000 Units
$360.34
$360.34
Coat/Print/Varnish (Outside)
9.89
9.19
Each Additional Print
3.14
2.61
White Dome
2.60
2.60
White Bottom
1.64
1.64
Base Price
In 1989, there were reportedly twelve marketers or contract fillers in the U.S. who were capable of filling Sepro cans. 411 but two o r chree have relatively low-speed Terco. Inc. gasser-plugger equipment, generally rated at 40 cans per minute.
One filler (Aerosol Services. I n c . . City of Industry, CA)
has two such lines. Since 90 to 951 of the present product mix is the post-foaming, gel-type shave creams, where the concentrate contains 4 to 5 volume percent of very volatile hydrocarbon material [typically isopentane. boiling at 86'F concentrate preparation and filling can be dangerous.
(30°C)],
The major filler. S.C.
Johnson h Son. Inc.. chills the concentrare (vithout hydrocarbons) to around 38'F
(4'C)
in a closed system, after which the hydrocarbon blend is added.
Because of the low temperature, foaming is avoided, even when agitation is applied.
The finished concentrate is filled into cans under explosion-proof,
Description of Aerosol Packaging Alternatives
well-ventilated conditions.
303
Other methods meter the concentrate and hydrocar-
bon portions together undetr cold conditions just before the filling step.
The
option of adding the gas-free concentrate, and then the pure hydrocarbon blend--or of adding the gas-free concentrate. crimping on the valve, and then pressure loading the pure hydrocarbon blend--is seen as a possible alternative for less gel-structured fornulations.
These "looser' dispersions would allow
intermingling of the hydrocarbon liquid within a reasonable number of days or weeks.
Since the bags are co+letely
full, hand or mechanical shaking of
finished units is of relatively modest benefit.
The process is best served by
filling the concentrate (gas-free) in very warm 122'F
(50.C)
conditions,
adding the foamant gas by Through-the-Valve (T-t-V), hot-tanking, and then mechanically shaking cans or cases of cans at the end of the line. The 1989 prices for several Terco. Inc. machines required for these functions are shown in Table 45. The present sales outlook for Sepro Cans is uncertain.
Post-foaming g e l -
type shave cream marketers are studying the option of a piston version of rhe same can size, and one has market-tested the concept.
Because of the high
price of the Sepro Can and the availabilicy of improved versions of the piston can in both tinplate and aluminum containers, most of the limited activity i n this field centers in the piston area. Bi-Can Around 1987, after extensive research, the Sutton Aerosols Unit, Hetalbox Aerosols & Toiletries Packaging Division, their version of the Sepro Can.
Group, p.1.c. (England) launched
Except for a longitudinal bulge, their nylon
bag firs snugly co che can body, leaving only a 1/8" (3.18-mm) high space at the Cop and a somewhat larger volume at the bottom for the exospace propellant.
Several can sizes are available. One is 115/114-200 x 515 (50-mm
inside diameter by 150-mm inside wall height), while another is 112/113-114 s 312 (45-mm i.d. x 95-mm i.w.h.).
304 Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 45. PRICES FOR TERCO, INC. GASSER-PLUGGERS (1989) ~
Production Rate'
Type Operation
Cost (Dollars)
40 c/nin.
Rotary Indexing
$26,063
40 c/min.
In-line
$45.758
80 c/min.
In-line
$56 355
120 c/min.
In-line
$77,040
120 c/mineb
In-line
$88.600
I
'Bottom charging and plugging unit only, except as noted. bBottom charging and plugging unit, plus through-the-valve gassing of hydrocarbon foamant.
Description of Aerosol Packaging Alternatives
305
The standard closure is a 3.5-mm pierced hole in the base, which is sealed by a short length of 5.0-mm diameter 80-Durometer nitrile cord after propellant injec tion. Before the formal introduction of the Bi-Can at the Interpack trade show in Dusseldorf, West Germany. Metrlbox worked vith Aerosols International, Ltd. (England's largest contract filler) for over two years getting them ready to produce Bi-Can produces on a medium-speed line having a capacity of about ten million units a year. lion Bi-Can units.
During 1988, the line actually produced about.3.5 mil-
As in the
U.S., nearly all the business was in the popular
post-foaming shave cream gel area, with products by Cillette (well over two million units), Wilkinson Sword, Tesco, Marks h Spencer, and Medicare. The Bi-Can (short for "Bag-In-Can") is now being promoted for additional applications, including "Nappi" coffee concentrate, t v o toothpastes, a line of artist's pigments, petrolatums, lithium greases, catsup and mustard, jellies, medicinal liquids, soft- to medium-viscosity caulking compounds, syrups, honey and flavored honeys, medicinal liquids, and cake icings. Baby oils and skin lotions have been demonstrated to customers. Were it not for the high cost, and sometimes the relatively small size o f the package, bag-in-cans might be a vary high-volume item.
The ability o f
these units to contain and deliver products is summarized below: Can deliver, as well as contain; Cannot be spilled; Can be made sterile by autoclaving, and will remain sterile during use ; Can be packed essentially air free for ingredient stability; Can handle liquids with viscosities of 1 to 1,000,000cps. at ambient temperature;
306 Alternative Formulations and Packaging to Reduce Use of CFCs
0
Can be packed and maintained moisture free (important for moisturepolymerized functional organo-silicones, for example);
0
Are noe messy to use;
0
Are highly directional in application (controlled spray);
0
Can be used with container in any convenient position;
0
About 987 of the contents can be dispensed--more than many other packs ;
0
No risk of product contamination by metals, except stainless steel valve spring (The Netalbox "Netpolam" laminared valve cup may be needed) ;
0
Highly concentrated product forms can be dispensed;
0
With proper propellant selection, such as nbutane, the package can safely vithstand temperatures up to 212'F
0
(1OO'C);
Applicable to post-foaming gels, as are the related piston-can and Enviro-Spray bag-in-can packs;
0
No concentrate evaporation is possible;
0
The propellant is only 1 to 2% of che total contents for most products and is likely to be incinerated with the empty can;
0
Can dispense product as a spray, foam, post-foam. liquid, paste, or
gel; 0
Available in 3- to 9-fluid ounce (30 to 226-mL) bag volumes;
Description of Aerosol Packaging Alternatives
307
Bags with as many as four different materials in up to four layers (including aluminum) are available for maximum resistance to permeation, ensuring shelf lives of at least three years in tests to date ; With the better bag shape and improved filling techniques, thick items can be filled without refrigeration or spin-filling options;
0
Low-pressure mixtures of special properties may be packed, such as a water and dimethyl ether mixture, which provides high solvency and soon evaporates completely:
0
The package is triply tested:
during can-making, when the bag is
inserted, and during the bunging or plugging operation;
0
A wide range of delivery rates is available, depending on choice of
product viscosity, exospace propellant pressure, and valve orifice sizes; and A total
of 23 "Trimline" sizes are potentially available, from 100
to 1.114 mL. Metalbox, now actually CHB Packaging, Ltd., formed by the merger of Croupe Carnaud, S.A. and Metalbox Packaging, Ltd. in 1989.. declares that the Bi-Can is not an aerosol.
This view is upheld by the British Aerosol Manufac-
turers Association (BANA), and several European regulatory bodies (such as COLIPA) that have published conclusions on this subject.
Bi-Cans are pre-
sently being shipped within the United Kingdom as non-aerosol commodities.
Around 1973, Aerosol Services Moehm, S.A. of Switzerland (now ASM. S.A.) developed a Lechner" aluminum aerosol can with a U P E vertically pleated bag and a valve cup lined heavily with plastic.
Several sizes were offered, with
diameters of from 1 3/8" to 2 1/8" (35 t o 52
mm).
Product leakage ar the
308 Alternative Formulations and Packaging to Reduce Use of CFCs
complex interface of can bead, bag flange, and valve mounting cup vas a problem.
Products such as Blendex toothpaste and a paste-type shampoo
concentrate lost marketshare and this forced the company to look for refinements.
This bi-compartmented aerosol used a very thin aluminum tube with a flat base and flanged top as the inner container. This eliminated the gas permeability that had plagued the previous design, the LDPE bag.
A l s o , if the
system was combined with a seal of epoxy resin at 'the crimp area, using air as the propellant, it offered a three-year shelf life, guaranteed by the supplier. The inner tube, or "Alu-Bag,"of D-1 (Heat-Killed, minimum temper) aluminum was generally 0 . 9 9 2
f
0.003" ( 2 5 . 2 2 0 . 0 8 mm) in diameter and
typically 6" (151 mm) long, or about 1/2" ( 1 2 . 7 mm) shorter than the outer aluminum can. Under the 3/32" (2.4mm) top flange there is a thin neoprene rubber gasket, which is the area that can be improved by sealing with epoxy. The valve cup is fitted with 0.040" (1.00 mm) neoprene or buna-N rubber gasket, called a cut (or lathe cut) cup gasket, since this affords a more reliable seal than the Weiderholder or other Flowed-In, vater-based neoprene gasket types. The aluminum inner tube offers more resistance to pneumatic crushing than its plastic counterparts; therefore, it is necessary to use a fairly highpressure propellant in the exo-space between tube and can. At least 28 psig ( 2 . 0 bar) of pressure differential should be available or dispensing will be
incomplete. The aluminum tube is (rarely) susceptible co a kinking type compressive distortion; therefore, it is useful to insert a length of polypropylene capillary tubing in it before filling with the concentrate. Typical dimensions are 90 t o 95X of the length of the tube and 0,090" 0.d. by 0,060" i.d. ( 2 . 2 9 x 1 . 5 2 mm).
Description of Aerosol Packaging Alternatives
309
The i.d. of the outer can is typically 30 to 35 rmn, which means that the volume of the exospace is greater than that of the inner tube or bag. Air or nitrogen pressure can then be used, and the pressure will not decrease substantially during tube collapse, unlike the situation with Sepro-Cans and Bi-Cans. Since less than 1.0 g of air or nitrogen is used, the degree of hermetic sealing must be very good. The Alucompack development vas used for toothpastes, a caulking compound for bathroom crack and crevice filling, and three medicinal items. Aerosol Services. A.G. performed the filling. They developed a technique of adding hydrocarbon propellants, first strongly cooled, into the outer can. Of the 3 to G grams poured into the can, perhaps 1.0 to 1.5 grams evaporated before the evaporation stopped. Meanwhile. the inner tube, smeared with epoxy, vas slid through the one-inch (25.4-rmn) opening and quickly filled nearly full vith product. The capillary tube vas inserted. The valve, without dip tube, was placed in position and hermetically sealed. When pouring isobutane. propane, and their mixtures into cans, these dispensers were never filled outside of Europe. Approximately 1.7 grams of liquid hydrocarbon are released when Under the Cup type gassers release aerosol cans, and this is the major charging method employed in the U.S. and Canada. Hicro-Comoack The third variant, by ASM of Switzerland, is a smaller version of the Alu-Compack. generally holding about 10 to 15 mL of product. Such products
as
a "small area" depilatory (for facial hair, moles with hair, etc.), an antiwrinkle (Retin A) cream, and various medicinal ointments are filled in these small dispensers. The 13- to 20-mm diameter ferrule-typevalve is attached by standard 18- to 24-tine mandrel clinching techniques.
310
Alternative Formulations and Packaging to Reduce Use of CFCs
W h n e r (Twes I T
h
r
u
The L e c h e r CmbH System I can vas developed around 1974 and consisted o f a vertically pleated LDPE bag in an aluminum can, sold with or without a nitrlle rubber plug in a 3.5-rpn hole in the base.
The filler can pressurize
and seal the can w i t h a gasser-plugger machine, or, with the plug in place, with a syringe needle that penetrates the plug.
The Aerofill, Ltd. firm in
England is one supplier of syrfnge gassers; they claim their hardened steel needles can last for filling up to 60,000 cans.
The needles are eventually
weakened by dulling and abrasion from the filler substances in the nitrile rubber plugs. System I is limited to LPDE. and (now) HDPE (D1018) bags in seven sizes ranging from 50 to 400 mL.
Such products as antiseptic sprays, household and
car cleaners, medicinal and veterinary products, contact lens cleaners, disinfectants, depilatories, and air fresheners have been sold in these packages.
Despite the sales efforts of Lechner USA Ltd., nearly all these
products are sold only in Europe. The System I1 dispenser has been more successful.
It uses an inner
aluminum bag and outer aluminum can, with top double seam and a dome that may be either aluminum or tinplate.
The extruded. cut off and flanged outer can
and inner bag are fitted together and triple seamed to the dome. gassing as described for the System I unit.
It uses base
Introduced around 1978. it is
available in 14 sizes (18 bar), two at 15 bar (217.5 psig minimum burst), and one at 12 bar (174 psig).
The last size is the largest: 502 mL. which was
originally conceived for holding highly acidic hair coloring paste and for use wich very high-viscosity silicone-based caulking compounds for commercial uses, but it is now used to dispense a wide variety of products.
One inter-
esting use for both this and the Ah-Compack is as the power unit for a nail dispenser.
A
particular gas blend of allene and methylallene. having a
pressure of 90 psig at 70'F
(6.33 bar at Zl'C),
is filled to a capacity of
100% into aluminum bags surrounded with propane, which has a pressure of 108.5
psig at 70'F
air free (7.64 bar at 21'C).
A
micro-metering valve located
outside the can feeds a tiny amount of "MAPP Gas" to the firing chamber of a
Description of Aerosol Packaging Alternatives
31 1
very small spring-loaded ram cylinder when a triggering mechanism is pressed. A minuscule spark plug explodes the mixcure above the piston-ran, and the ram then moves outward to drive in a nail, separated from a nail-pack and held in
In this way, nails can be driven into wood as fast as one can pull the trigger.. A 3.99-fluid ounce (117.98-mL) charge of KAPP Gas position belov the ram.
can sink thousands of nails. A number of topically applied medicines and drugs are under test in
small versions of the System 11 dispenser.
The 3H, Inc. firm uses it for
their fuel injector engine cleaner, since it is important that only the liquid phase enter the engine for spark plug and upper cylinder area cleaning purposes. 275.4.F
Prescription dental gels and gum cements are conveniently disOne new drug under development in
pensed.
(135.C).
Curope requires autoclaving at
After the filled System I1 unit is processed, heated, and
cooled, it is gassed and plugged. The Lechner System 111 dispenser consists of a conventional aluminum can, but heavily lined in such a way that the lining adheres tightly only at the crimp and upper dome area.
The rest is very loosely attached. When the can
is filled with concentrate and sealed, gas is injected through the hole in che bottom, causing the bulk of che lining to separate from the can surface and become, in effect, a bag.
The base hole is then plugged.
(Syringe filling
cannot be done for fear of perforating the adjacent bag material.) The modified polyolefin lining is suitable for a wide range of products.
In fact, virtually any cream, gel. lotion, ointment. paste, o r liquid now packed in a plastic tube or bottle can be more conveniently packed in the System 111. At least 98Z will be discharged. Finally, the Lechner System IV is a modification of the System 11. that improves o n che relatively poor aesthetics of the triple-seamed dome design. It looks like a standard aluminum (one-piece) aerosol can. The larger version (25.4-m) opening will be available by October 1989. and smaller
with a 1 '
ones, using a 2 0 - m ferrule type valve, will come onto the market about March
Alternative Formulations and Packaging to Reduce Use of CFCs
312
1990.
They will have a 0.98” (25-mm) diameter at first, but other diameters
will be available later on. The most significant of the Lechner developments is the System 111 dispenser, since it eliminates the preformed bag as such, and thus eliminates about a third of the component cost.
This considerable economy should do much
to stimulate volume growth of the No-compartment dispensing system.
In 1976. this vertically pleated medium density polyethylene (MDPE) bag in aluminum or tinplate can development vas completed by a West German firm in Hamburg.
By the following year, w o West German and one French firm announced
they were ready to supply it commercially.
However, because of seepage
problems around the crimped seal (especially in the case of the aluminum cans), the dispensers were sold in relatively small quantities for abouf t w o years and then discontinued. Other Ban -In-C a w A number of additional bag-in-can designs have not achieved commercial success, sometimes in spite of excellent designs.
One of these, developed in
California and taken over by the (then) American Can Company, used a “cup“ of polyethylene or laminate structure, attached via the top seam of a regular tinplate can.
Production problems consisted of trying to uniformly air b l o w
the plastic cups inco waiting “domeless” cans, and trying to eliminate the “2”s o r “switchbacksc that occurred over the flange.
When these triple
thickness areas of plastic were wrapped into the top triple seam, actually a sextuple seam resulted, which leaked slowly or latently at the fold interfaces.
The companies eventually halted product development.
Description of Aerosol Packaging Alternatives
313
PISTON CANS As with the Sepro can, this compartmented package requires less pro-
pellant than a conventional aerosol package.
Probably the first commercial
piston can was developed in 1961; it contained about & Av.02. (113.4 g) o f Brylcream in an aluminum two-piece container with a free piston of mediumdensity polyethylene (HDPE)
.
Until about 1988, there was only one piston supplier in the U . S . . the American Can Company (now the American National Can Division of Pechiney, S.A.), who supplied a No-piece aluminum Kira-Flo container.
There are
several in Europe and at least one in Japan. During 1974. a drawn-and-ironed two-piece steel can was manufactured for the U.S. Borax and Chemicals Company's "Boraxo" waterless hand cream. The can was a seamless steel type, with top double seam.
The problem with soldered
and other welded side seam steel cans was that the polyethylene pistons could not fit the can wall snugly in this side-seamed area, and this caused "blowby" of the gas past the piston wall and into the product, where it usually dissolved and lost its pressure.
In fact, aluminum cans with wall dents were
probable candidates for blow-by problems.
During 1986, innovations in side-
seal technology created the smooth side-seam profile, improving on earlier constructions of the "stepped" type. The tinplate or tin-free steel (TFS) cans are probable candidates for piston can modification.
They are approximately 2OY less costly than aluminum
and are available in sizes of 100-mL to 1114-mL total capacity.
The metal is
also harder and less vulnerable to pre-filling or post-filling denting problems. The Mira-Flo Can
Experimental piston cans date back to 1956. when Crown Cork C Seal Company used a crude piston, over a large, compressed, steel spring to dispense various food produccs from their 202 x 406 Spra-tainer can.
The
314
Alternative Formulations and Packaging to Reduce Use of CFCs
spring provided backup pressure in case of propellant leakage.
American Can
Company began vork on a two-piece 202-diameter aluminum can about 1960. and in 1962 they introduced their Mira-Spray (single compartment) and Mira-Flo (piston-type) 202 X 406 containers.
The Mira-Flo had a 9/64" (3.57 mm)
punched hole in the base. suitable for gas injection followed by plugging with a cord of 70-Durometer neoprene rubber. The n e w cans were made at a plant that had an initial capacity of 38,000,000 units a year.
Since the price of the Mira-Spray can vas somewhat
higher than that of the highly similar, steel, two-piece Spra-tainer made by Crown, sales were very poor. American Can Company promoted the Mira-Flo cans, which were made on the same production line as the Mira-Spray cans, except that an LDPE piston and pierced base section were inserted.
Samples containing domestic and imported
cheeses were shown to Kraft, Nabisco. General Foods, and others from 1961 through 1963.
Samples containing oleomargarine and thick chocolate syrup were
s h o w t o Maatole and Bosco product managers at the Best Foods Division of CPC International Inc. An experimental margarine sample, prepared at the American Can Company's Barrington. IL Research Center for the Land 0 Lakes Co.. Inc. survives today, works well, and still contains product that has a good, fresh taste after 27 years. After a few years, the capacity of the production line vas reached: approximately 1,000,000Hira-Spray cans for various small uses (such as air fresheners), 33,000,000 Mira-Flo cans with various types of cheese, and 4,000,000Mira-Flo cans with various colors of Pillsbury's Cake Topping for
creating decorative designs and/or messages on cake icings.
The coggle-action
Clayton Corporation food valves were supplied vich several alternative actuator tips (in the case of the cake toppings) to create extrusions with star shapes, ovals, etc., in addition to the standard round ribbon.
Instead
o f the more costly aluminum option, American has turned to the welded rinplate
piston can.
Description of Aerosol Packaging Alternatives
315
While many fairly complex piston profiles have been developed (mainly in Europe) over a thirty-year period. in 1987 American pioneered the "freefloating type:
a piston that had t o expand slightly t o reach the can walls.
It requires the product to have a viscosity of over 12,000 cps at ambient temperatures, The novel pistons use a "gasket" formed by the product itself t o effect the seal and inhibit gas by-pass.
The second innovation w a s commercialized in late 1986.
Known as the
"umbrella valve." it is a form of rubber plug shaped like a mushroom. applied from inside the can bottom. pushed into the can. upon insertion.
It is
Small ears prevent the plug from being
The larger umbrella top is flexible enough to compress
Once the plug is in the can, the internal pressure forces i t
downward, making a tight seal.
The new valve allows filling speeds of up to
360 cans per minute. Disadvantages of piston cans are that they require products of reasonably high viscosity that do not distort the piston.
Piston by-pass (or blow-by)
and permeation can cause problems by reducing the quantity of gas below che piston and perhaps by causing foam generation in the product.
If the product
is not compatible with the can, this can be a bigger problem with piston cans than vith bag-in-can types because of the direct exposure of can surfaces to the product.
N e w . very heavy linings are being developed by CMB Products,
Ltd. and others t o counceract chis shortcoming.
Some of the linings are
bonded polypropylene approximately 0.010" (0.25 mm) thick, and they can also be used for the double seam sealing material. Other Piston Cans Piston cans using aerosol containers have been marketed by Advanced Monobloc, Ltd. (Division of CCL Industries, Ltd.. Toronto, Canada), the Continental Can Group of United State Company. Inc., Boxal/Alusuisse. Cebal/Pechineiy, S . A . . Hoell. GmbH (Hamburg. Uesc German), Rocep Pressure Packs, Lcd. (Clasgow, Scotland) and a firm in Japan.
Except for the Rocep
units. most are typical piston cans and conform to the description of "Mira-
316
Alternative Formulations and Packaging to Reduce Use of CFCs
Flo" units.
Perhaps the largest manufacturer is the U.S. Can Co., since they
nov have a considerable share of the shave cream business. Rocep cans are unique in that they are often quite small, such as 1" ( 2 5
mm) in diameter, and sealed vith a 2 2 - m type ferrule valve.
However. the
main difference from others is that they use a double piston:
two rather
shallov types, one below the other. vith the small space in between filled vith mineral oil.
The purpose of the oil is to capture and retain any
propellant that panetraces through or around the lover piston, so that it will not go further upvard and get into the product.
Another unique feature is the
"lever pack" package design. vhere the valve turret head is turned varying degrees on an eccentric track to control dispensing rates.
Dispensing can
then be actuated at various rates by depressing a 3 to 4" (76 to 101 mm) wire profiled lever against the can.
This type of control is perfect for sealants.
among other products. Silicone acetate or silicone aminofunctional caulking compounds, which turn to a rubbery mass vhen brought into contact vith humidity or moisture illustrate this product type.
These products cannot be allowed to contact the
liquified propellant or various degrees of foaming would take place as they were dispensed, leading to a strange-looking and less-effective seal. Under such trade names as "One Tough" Silicone Sealant blister packs containing three-ounce (80-g) piston cans are being sold at $5.95 to $6.95 each. Standard trigger-type caulking gun packs vith tvelve times as much of the same product are sold for $ 4 . 0 0 to $ 4 . 5 0 in the same stores.
An interesting alternative to the piston can is a pressurized pack designed to clamp onto one end of a standard caulking canister, filled with organo-silicone, acrylic, butyl or thiokol sealing compounds.
An
independent
plastic piston is pressed into the cylinder by finger-pressure on an actuator. When the finger pressure is released, the gas pressure is automatically discharged upward, out of the orifice in the actuator. This instantly stops the flow.
Description of Aerosol Packaging Alternatives
317
The Rocep package uses a nonflammable mixture of HCFC-22/142b (40:60)for a pressure of about 83 psig at 70'F
(5.85 bar at 21.C).
including the partial
pressure of trapped air. A major problem developed when the relatively high pressure and solvent action of the propellant blend softened and squeezed the neoprene plugs out of the pierced holes in the tinplate can bottom, thus depressurizing the units. Short of using CFC propellants, there is no lower-pressure, nonflammable propellant currently available.
The issue was finally resolved by moving to a
slightly thicker nitrile plug and punching the hole in such a fashion that a slightly ragged lip was formed at the inner rim of the hole to act as a barb. Even so. extended storage at 130'F
(51r.4.C) will cause expulsion of the plug.
Recent findings suggest that a trace film of mineral oil (from betveen the pistons) is a contributing factor.
The final difficulty with this package is that the container itself is composed of a special aluminum top and wall extrusion, but the base is of tinplate. An uneasy junction of these two metals at the bottom double seam is produced after the silicone product and double piston assembly are added.
The
tinplate tends to cut into the much softer and thicker aluminum, resulting i n a 6.2% leakage rejection rate at the factory hot-tank tester. Technology exists to double-seam dissimilar substances, even plastic container walls to tinplate end sections, but it is not very effective for small-diameter closures such as the 1" (25.4-mm)diameter container. Apart from the silicone-based specialty bathroom tub and tile sealants just discussed, no other products have yet been commercially produced in t h i s packaging form.
The high production cost, partly due to high scrap rates, i s
considered to be a major factor. The Boxal Pumu DisDenseC During the Internacional Packaging Exhibition (Pakex 89; Birmingham, England: April 21, 1989) the Boxal Group. a member of Alusuisse Packaging
318
Alternative Formulations and Packaging to Reduce Use of CFCs
Division. shoved t h e i r standard piston-type aerosol can, a s well a s a new, p r o p e l l a n t l e s s version that operates on a vacuum s u c t i o n p r i n c i p l e . Using a custom-made valve by Coster. S.A. and a standard a e r o s o l - t y p e aluminum can with inner p i s t o n and perforated bottom ( b u t no p l u g ) , the u n i t provider a metered f l o v of product whenever t h e a c t u a t i n g spout is operated. Lotions, creams, and pastes may a l s o be dispensed.
Uhen t h e pump a c t u a t o r is depressed, a low vacuum i s c r e a t e d i n the product compartment.
Through the hole (1/16" o r 1.6 mm) i n the b a s e , atmo-
spheric pressure then presses the HDPE p i s t o n upvards a small d i s t a n c e .
The
pump is constructed t o prevent any contact between product and a i r u n t i l the m a t e r i a l is discharged from the dispenser. The pump s t r o k e volume can be adjusted according t o product c h a r a c t e r i s -
tics and according t o marketer requirements.
P a r t i a l s t r o k e s w i l l extrude
correspondingly less product than f u l l s t r o k e s .
Because the pressure d i f f e r -
e n t i a l (betveen a p a r t i a l vacuum and normal a i r pressure) is r e l a t i v e l y low, the unit is not s u i t a b l e f o r highly viscous products.
They would emerge too
s l o v l y f o r customer s a t i s f a c t i o n . The development is not inexpensive, due mainly t o the c o s t of the s p e c i a l l y designed Coster. S . A . pump-action valve.
I t does provide a new and
a t t r a c t i v e packaging form f o r creams, g e l s , p a s t e s , l o t i o n s , and o t h e r l o w - t o medium v i s c o s i t y products i n the cosmetics, t o i l e t r i e s . pharmaceutical, and food a r e a s , usually giving those products prolonged s h e l f l i v e s i n comparison with packaging i n j a r s o r b o t t l e s .
Evaporation, a i r oxidation, fragrance
d e t e r i o r a t i o n . s p i l l a g e , and breakage a r e a l l avoided. f i l l e d on standard aerosol equipment a t high speeds. material can be dispensed.
The products can be From 96 t o 9 7 . 5 % of the
In the U.S., unlike a e r o s o l s , the a c t u a l content
( i n f l u i d ounces), r a t h e r than the dispensed weight, is the b a s i s f o r the d e c l a r a t i o n of contents on the l a b e l .
However. l a b e l i n g requirements will
vary with the country having j u r i s d i c t i o n .
319
Description of Aerosol Packaging Alternatives
In one instance, an aqua-colored, rather viscous specialty shampoo vas found to change color rapidly, tovard green, then olive green, and finally yellow when packed in glass and exposed to sunlight.
No color change has yet
been seen in this product when packed for eight months in the Boxal pump dispenser.
INDEPENDENT BAG-IN-CAN SYSTEM During the late 1950a. inventor Ellis Reynar began to introduce aerosol marketers and fillers to his patented process for a product designed to In its simplest form, his
permanently separate the propellant and product.
innovation consisted of a plaocic pouch, to be inserted in an aerosol can, either before or after filling with the concentrate. chemicals: sodium bicarbonate (NaHCO,) acid [C,H,O(CO,H),]
The pouch contained two
powder and a 502 solution of citric
in separace burscable tubes.
When the two chemicals come
together, during a deliberate rupturing process directly ahead of the valve insertion and sealing operation, they chemically react to produce various sodium citrate salts and carbon dioxide ( C o t ) gas.
The outer envelope of the
pouch remains intact, but it swells as a result of carbon dioxide pressure and presses against the can and the contents, so that vhen the valve is actuated, product flows out of the can as a coarse (non-aerated) spray, as a gel, paste, post-foaming gel, stream, or foam. A problem with the early developments vas that the bag vas subject to gas
permeation. stress cracking, product influences, and imperfect velding.
These
problems were solved by using laminates, often including a core layer of
0.0005" (0.013 mm) aluminum foil to almost totally eliminate any permeation. A less-effective barrier material is Mylar (polyethylene terephthalate -
biaxial), which also ad&
considerable strength to the bag.
A second problem was that the bag could initially swell up only to che
volume of the gas space over the concentrate.
Because o f various government
regulations limiting aerosol pressures to about 180 psig at 130'F at 54.5.C).
(12.68 bars
the practical maximum pressure that the bag could exert ac room
temperatures vas 142 psig (10.0 bars), and many marketers were more comfort-
320 Alternative Formulations and Packaging to Reduce Use of CFCs
able vith 60 to 80% of this level.
Following is an example of the pressure
decrease during use that would take place for a typical product: Product:
Toothpaste.
Volume Fill:
250 mL of toothpaste,
M
m L for pouch, and 140
mL for head
space over the toothpaste. Pressure :
140 psig at ambient temperature
-
initial. (9.86 bars)
Head space air compression to about 10% of original
Note:
volume, plus absorption of some of that into the toothpaste, is not considered here.
(Can be reduced by vacuum
crimping.) After the essentially complete discharge of toothpaste, the pouch volume will increase from 10 m L to 400 mL. After the initial step of gas formation in the bag, it swells to 140 mL and has a pressure of 155 psi-absolute at ambient temperature. Using Boyle's Lav. the pressure drop during toothpaste expulsion will be: p,
P,
-
-
pi
(",/v,)
-
155 (140/400)
-
54.25 psi-absolute
39.25 psig (2.76 bars)
Thus, the gauge pressure at ambient temperature is reduced from 140 to 39 psig (9.86 to 2.76 bars).
Repeating this study using an initial gauge pressure of 100 psig. would result in a final (can empty) pressure of only 25.25 psig (1.78 bars).
This
degree of pressure drop will result in significant decreases in delivery rate. especially for viscous products of positive yield point, during package life. This drop can be reduced by using what has been termed a "functional slack fill" of product. such as a 50-volwne percent quantity, but this increases t h e
cost per unit weight or volume of product and has other disadvantages.
Description of Aerosol Packaging Alternatives
321
Around 1975. t h e Grow Group, Inc. became i n t e r e s t e d i n the Reyner system, thinking it could be r e f i n e d t o d e l i v e r a c e r t a i n amount of gas a t the o n s e t , and t h a t maintenance amounts could be provided as needed during use.
Afcer
a
research period l a s t i n g two y e a r s , t h e Grow Group announced the a c q u i s i t i o n o f Reynsr’s interests and t h e formation of Emriro-Spray Systems, Inc. t o promote and s e l l the improved pouches and f i l l i n g technology t h a t had been developed.
The pouch now contained one f a i r l y l a r g e inner container of 50% c i t r i c a c i d s o l u t i o n i n water, p l u s s i x o t h e r much smaller c o n t a i n e r s .
The Larger
r e c e p t a c l e could be t o r n o r ruptured, e i t h e r by s t r i k i n g the i n s e r t e d bag with a small ram, o r by the a c t i o n of the vacuum crimping operation, r e l e a s i n g the contents and generating from 60 t o 100 p s i g ( 4 . 2 t o 7 . 0 b a r s ) of carbon dioxide gas.
As t h e product vas used, t h e bag expanded a s t h e head space
expanded, and a t a pre-engineered p o i n t t h e f i r s t smaller compartment of c i t r i c a c i d s o l u t i o n vas breached. level.
This returned the pressure t o t h e o r i g i n a l
The process w a s repeated u n t i l the l a s t c i t r i c a c i d r e c e p t a c l e had
been ruptured. With t h i s s o r t of arrangement, t h e pressure could go ( f o r example) from 100 p s i g t o 80 psig. back t o 100 p s i g . down t o 77 p s i g . up t o 103 p s i g , e t c .
a s many times a s there vere c i t r i c a c i d receptacles.
The r e l a t i v e complexicy
o f having pressures of over 60 t o 80 p s i g ( 4 . 2 t o 5.6 b a r s ) vas questioned
during the development of t h i s system, a s vas the need f o r s i x maintenance system bags.
Four of these appeared t o be adequate, and f u t u r e e d i t i o n s o f
che pouch u l t i m a t e l y used only four. Other refinements include adding a flow tube, which consisted of a s u i t a b l e length of aerosol valve dip-tubing so t h a t the expanding pouch would not press hard a g a i n s t the middle o r upper potions of the can w a l l and c u t o f f o r t r a p product below t h a t p o i n t , keeping i t from being discharged.
Finally,
the r e s e r v o i r o f sodium bicarbonate vas contained i n a water-soluble polyvinyl alcohol p l a s t i c , so t h a t when the water-impermeable membrane betveen the primary c i t r i c a c i d sack and sodium bicarbonate compartment was d e l i b e r a t e l y ruptured by ram o r vacuum a c t i o n , the pouch would not i n s t a n t l y i n f l a t e , b u t
322 Alternative Formulations and Packaging to Reduce Use of CFCs
would be delayed f o r one minute t o allow time f o r the valve crimping ( o r s e a l i n g ) operation. Since the bag would be expected t o i n f l a t e after the package w a s s e a l e d , a way had t o be found t o a u t h e n t i c a t e that it had a c t u a l l y expanded.
On
production l i n e s t h i s w a s done by means of X-ray based l e v e l measuring Pressure measuring could be p e r f o r m d on a laboratory o r s t a t i s t i -
equipment.
c a l production quality assurance s c a l e , and t h i s a l s o showed i f only the main c i t r i c a c i d r e c e p t a c l e had ruptured.
One problem with t h e system, even i n
units produced i n 1989, is that w o or more of the c i t r i c a c i d c o n t a i n e r s can rupture i f t h e r e is a problem with bag q u a l i t y , r e s u l t i n g i n excessive i n t e r n a l pressures. Figure 4 d e p i c t s a slow-speed aerosol l i n e , using semi-automatic pouchs t u f f e r s . r a t e d a t about 18 u n i t s per minute f o r each of the two machines i n
use.
The rest of t h e line is f a i r l y standard, except f o r the l e v e l checker,
which is w e d t o ensure pouch i n f l a t i o n .
The p r e f e r r e d valve is the Precision Valve Corporation Model 1-NN, with a 2 X 0.5-mm stem s l o t t e d "Enviro-Spray" type housing. button or spout may be used.
Any type of a c t u a t o r
The standard pouch is designed t o be used with a
202 X 514 (53-mn diameter X 300-mL) can with a 170-mL product f i l l . The firm suggests the following product p o s s i b i l i t i e s : A i r Fresheners;
Plant Sprays:
--
--
_-
Leaf Shines, Aphid c o n t r o l , F e r t i l i z e r Concentrates;
Petroleum J e l l y ( f o r example, f o r b a b i e s ) ; Bathroom Cleaners; Toothpaste; Post-foaming Gels ( a s shave creams): Metered Dispensing (micro and macro); Toppings ;
Description
Figure
4
Slow-Speed
Grow
of Aerosol Packaging Alternatives
Pak
Packaging
323
Alternative Formulations and Packaging to Reduce Use of CFCs
324
Cheeses or Snack Items; Waterless Hand Cleaners and Related Lotions; Pet Care Items;
--
--
_-
Groomers, Shampoos
-
optionally insecticidal,
Flea 6 Tick Sprays (soundless);
Cake Decorations; Industrial Maintenance Items, including lubricants; Selected Coatings; Furniture Polish (in lotion forms); and Kustard. Catsup, Purees and so forth.
Those products actually marketed in the Enviro-Spray System include the following: e
Tomato and Vegetable Insecticide;
e
House Plant Insecticide;
e
Rose 6 Flower Insecticide;
e
Flea 6 Tick Spray for Dogs;
e
Flea 6 Tick Repellant Spray for Dogs;
0
Spray for Cats
e
Leaf Shine for Ornamentals;
e
"Le Gel" by Williams (Beecham) Shave Cream;
e
"Kouros" by Yves Saint Laurent;
e
"Algipan" by Labaz Sanofi- Rubifacient Cream;
0
"CCRF" Tomato Paste, Tomato Ketchup, and Mustard;
0
"Mist C Feed" Foilant Nutrient Spray; and
e
Beecham Caovel Pet Insecticide Spray.
-
Insecticide;
In 1986, costs were $3.59 to $8.99 for cans ranging from 7-AV.02. ( 2 0 0 - g ) to 32-Av.02. (946-g) net weight.
Containers were also sold for such s p e c i a l -
ties as institutional "gallon-size" insecticides. the pressurizacion of l o w gas beer kegs, soft drink dispensers designed to operate under "no gravity" conditions in the NASA space program, ecc.
The pet sprays benefitted from t h e
soundless delivery of the Enviro-Spray dispensers, since pets can hear and are
Description of Aerosol Packaging Alternatives
325
distressed by the very high-pitched sound of standard aerosol sprays, except for those pressurized by air or nitrogen gases. The second largest Enviro-Spray in Europe is a line of four food products by C.C.R.F. (France), under the brandname of Claude Vetillard.
They include
Tomato Puree, Double Concentrated 28% Mustard "Forte de Dijon," and Tomato Ketchup, packed to 280 g (250 mL) in metal box "Slimline" cans measuring 57 X
164 mm.
Each is fitted with a Precision valve and "captured plug" spout.
After 27 months, some cans of the Tomato Ketchup have shown a slight seepage
of the product at the juncture or top and si&
seams.
With appropriate
adhesive-backed fonnula and precautionary stickers, these cans have made a modest entry into the more expensive U . S . specialty shops, such as those at airports and major hotels. PUnP SPRAYS
-
ASPIRATOR TYPES
Pump-sprays have taken many forms.
There are those whose pressure is
generated within the meter-.spray valve, and others (much rarer) whose pressure is produced in the container by various means.
In the unique "Pre-Val" unit,
developed by the Precision Valve Corporation (1975). a glass or plastic jar is filled with product and then sprayed out by aspirating it up a dip tube leading into an upper "Pressure Pack" containing a liquid propellant.
When
the valve button is depressed, propellant gas is discharged, sucking up a certain amount of the concentrate and discharging it as well.
The usual ratio
is about 4 to 1, so that approximately 400 g of concentrate is dispensed by 100 g of a hydrocarbon blend.
necessary.
No solubility of propellant and concentrate is
If the concentrate might dry in the valve orifice to form a solid
clog. or after use. the jar portion can be disconnected and the valve actuated to blow the mechanism essentially free of all product.
The dispenser, along with refill units, can be purchased in hardware stores, lumber yards, and
similar outlets. The original form of the aspirator-type dispenser is the pump-sprayer f o r space spray insecticides. This normally consists of a tubular barrel (the
326 Alternative Formulations and Packaging to Reduce Use of CFCs
cylinder) and a thin piston at the end of a fairly long rod, as shown in Figure 5.
Figure 5.
The “Flit Gun* Aspirator-Type Insecticide Space Sprayer
The product is aspirated up a plastic or metal dip tube and through a j e c orifice that ends in the midst of a vigorous stream of air, at 10 to 20 psig
(0.70 to 1.41 bar), directed at it from a nozzle at the end of the cylinder. The ratio of low-pressure air to amount of aspirated product is the primary determinant of particle size distribution.
Ideally, the particle size would
be less than 3 0 ~ . Othervise. the larger particles would fall to the floor rather quickly and be of little use in killing houseflies. mosquitoes, and other flying insects.
The largest-selling insect sprayers have been a line
called “Quick Henry, the FLIT,“ sold by Penola Oil 6 Chemical Corporation, and later by Esso Oil Company, Humble Oil 6 Refining Co.. and still more recently by Exxon, Inc. These sprayers were often manufactured in very expensive forms, such as in nickel-plated bronze. vith decorative designs and printing (sometimes engraved), and vith small boxes of replacement piston “leathers” and spare glass jars that vere often customized and suitably embossed vith the name of che sprayer.
Quart (946 nL) cans of insecticides in low-odor kerosene
solvents vere available from Penola. Esso. Sinclair. Phillips, Conoco. Shell, Peneco. Gulf, Pennsoil, Rex, Sohio, Cook, and other oil companies, which would vork vel1 in any o f the available sprayers.
Description of Aerosol Packaging Alternatives
327
Today, a feu firms make all-plastic sprayers, except for the metal orifice areas, but they are not advertised, and sales volume is limited.
“F”-
style or cone-top cans of insecticidal concentrates can also be found, but availabilicy is also limited.
These sprayers are far more popular in coun-
tries other thoa the U . S . , Europe, and Japan. The aspirator-type sprayers are the only sprayers, other than aerosols, that can produce a space spray.
They have been so closely associated.
hovever, vith (smelly) insecticides that it vould not be possible to market them for air fresheners or for other uses in the U.S.
However, some “mini“-
sprayers of this type are occasionally available for household perfumes in Latin America, and the rubber-bulb type aspirator may still be seen for personal fragrancing applications, generally in rather fancy designs. Colognes are available in bottles exceeding one U.S. gallon (3,786 mL) capacity for refilling other containers and dispensers, so a supply of the product itself is not a problem. PUMP-SPRAYS
-
STANDARD TYPES
The most common pump sprayer is commonly called the finger-pump, mainly to distinguish it from the trigger-action sprayer. The finger pump is available from the same manufacturers that produce aerosol valves, such as t h e Calmar Corporation, Bakan Products Co., Risdon Manufacturing Co. (Division of CMP Products, Ltd.. as of 1989). Emson Research Company, and others. The largest is probably the Seaquist Closures Division of Pittway. Inc.. located in Cary, IL (U.S.).
In many cases, it takes an expert to distinguish between
a ferrule-type aerosol valve and a ferrule-type finger-pump valve: they are often made by the same company and have tvo or three components in common. Distinguishing features of the finger-action valve are its larger, more complex valve structure and its often clear plastic body component that displays a complicated spring above a metallic ball check unit. indicator is the type of container.
The best
If it is a plain glass bottle larger than
one fluid ounce (29.57 mL). or a small glass bottle with flat surfaces or
328 Alternative Formulations and Packaging to Reduce Use of CFCs
sharp comers, or a polyethylene or polypropylene or vinyl bottle, or if the bottle can be deformed by squeezing, or if the valve is attached by means of a screw-threaded connection, the valve is not an aerosol valve.
Some finger-
action valves are placed in one-inch aerosol cups and crimped onto aerosol cans.
These defy identification except by operating them.
The usual aerosol valve has up to s e v m components and sells for about
$40.00 per thousand.
In contrast, the finger-action valve has eleven com-
ponents, soma of which must fit together with tolerances more demanding than those of aerosol counterparts.
Consequently, these valves sell for two to
three times the cost o f the aerosol types, depending on size and other factors. An illustrative sketch of a typical screw-cap mounted finger-action valve
is shown in Figure 6.
The finger-action valve delivers a fixed amount of product per actuation, from 125 to 200 microliters. To convert this to milligrams per shot, simply multiply the microliter rating by the product density.
20% or more.
Densities may vary by
Ethanol solutions, such as hair sprays, have the lowest density,
at about 0.80 g/mL.
As the actuator is depressed, the adapter and stem components are forced downward as well.
The stem travels a fixed distance into the body chamber,
which is normally filled with product in the primed valve.
The product forces
the piston to expand outward, allowing product to flow past it and into the cross-hole orifices of the stem.
From there it travels up the stem hole,
through the adapter and button, and out as a stream, or spray.
When the
button is released, the spring forces the stem upward, creating a partial vacuum in the chamber and causing the ball to lift and allow product to flow upward to refill the body chamber with the product.
Description of Aerosol Packaging Alternatives
Figure 6.
Cross-Section of Finger-Action Seaquist Valve, Set in 22-415 Closure
329
330 Alternative Formulations and Packaging to Reduce Use of CFCs
The complexity of the finger-pump valve systems makes them sensitive to strong solvents, solid suspension products and thixotropic viscous products.
As a rule, they are only used for water-based, hydroalcoholic, and alcoholic formulations. The complexity of finger-pump valves is compared with the relative simplicity of a non-metering aerosol valve in the drawings presented in Figure 7.
The complaxity of the matering aarosol valve is more or less
equivalent to that of the pump-action types. Along with the complexity of thasa valvas comes a considerable increase in cost, compared with aerosol valve options.
Costs may be controlled by
using the largest practical containers (to lower cost per unit of product), by marketing refill containers that use simple screw-caps, and by emphasizing the
use of finger-pump valves with colognes, sachets, perfumes, pharmaceutical, and other generally high-cost products.
In the case of perfumes and some
medicinal items, the metering action of the finger-pumps is a distinct advantage in conserving and regulating the use of these products. The pressure build-up within the chamber of the finger-pump valve is a complex function of the pressure applied to the actuator, the size of the exi: orifices (diameter mostly, but also length), product viscosity, and other factors, but it is generally in the order of 50 psig (3.5 bars).
Mechanical
breakup spray heads do a fairly good job of developing spray patterns when the liquid is at a pressure of about 18 psig (1.27 bar) or higher.
A t excessive
pressures (rarely attainable) there is some denigration of the pattern, such as "hot spotting." The spray pattern and particle size distribution of finger-pump sprays is due to the purely mechanical breakup attributes of the specially designed twopiece button.
Two to four tangential channels converge the product into a
central swirl chamber, where it must turn at right angles to pass through the terminal orifice.
Description of Aerosol Packaging Alternatives
331
-J
C
4
- Nylon or
ACrtrL
A
A
A
B
P
B C D E F
c
c
B SIP(--c MouuTx~CUP-4lAlurinllm D rnmcASgET-Buna-N E BODY mlon or Acetal F -S SS-302 C DIPRIBE-CapFllarlPP
Y
H I
with 0.020", 0.030n or 0.040" I.D., or 0.125" I.D. Polyethylene
J K
J
c D
z
spbl
-
-
K L Figure 7 .
Comparison of Risdon (Dispensing Systems Division) Finger-Pump 20TNT Pump and SL-GO flfcro-flisr v s . 2011~Aerosol Valve
332 Alternative Formulations and Packaging to Reduce Use of CFCs
Unlike most aerosols, where exploding actions caused by the instantaneous depressurization of liquified propellant act to reduce particle size to various degrees, the particle size of finger-pump sprays is regarded as very coarse, and best suited for surface applications. As a rule, spray particles from finger-pump units will strike the floor within five seconds or less, regardless of the initial direction of the spray.
The only aerosols whose
sprays compare with those of finger-pumps are "nitrosols," those pressurized with 1 to 6 g r a m of nitrogen gas (depending on size), and water-based types designed to have the hydrocarbon propellant separate on top as a discrete layer. Most of these latter products, such as starches and fabric finishes, carry a top-of-can message of "Shake Before Using" to obtain a better spray pattern by incorporating'some propellant into the exiting product. The finger-pump particle size distribution is compared with those of several similar products in Table 4 6 . Spray patterns of the finger-pumps vary from quite wide to very narrow. The valve of the "Moi-Stir" Mouth Moistener (Kingswood Laboratories, Inc.) will cast heavy droplets in a 7" (180-m) slightly oval pattern onto a target panel 60" (1.51 m) distant. A "Hot Shot" Wasp & Hornet Spray (finger-action Calmar valve, ex. Bakan) by United Industries Corporation (St. Louis, MO), formerly Chemsico, Inc., will cast a narrow spray over 12 feet (4.35 m). Cologne sprays are usually the widest. with the particles traveling fairly slowly outvard.
In fact, cologne sprays, if deliberately ignited, will
quickly burn back to the valve button and burn the fingertip of the operator, unless the spray shuts off first. One of the detractions of the finger-action spray is the number of times the actuator must be depressed to empty the dispenser.
For example, consider
an 8.0-fluid ounce (299 mL) container, which is dispensed at the rate of 0.125 mL (125pL. or 100 mg) per shot.
The required number of actuations to empty
the dispenser will be 2,396. This number can be approximately halved by using finger-pump valves with 0.205 m L and similar size-metering dimensions. Many pump-spray marketers compensate for the slow use-up rate. compared with the
Description of Aerosol Packaging Alternatives
TABLE 46.
AEROSOL AND FINGER-PUMP HAIR SPRAYS: PARTICLE SIZE DISTRIBUTIONS Parr'cle
333
COMPARISON O F
S i z e Ranee (u)'
x of
Below
Type & Valve
Propellants
lop
Finger-Pump mechanical breakup (MB)
0
0
2
14
86
Aerosol Non-MB
20
1
5
38
66
Aerosol PLB
20
3
8
48
L1
Aerosol Non-MB
25
2
8
49
41
Aerosol MB
25
5
15
60
20
Aerosol MBb
16.67
0.5
2
22.5
75
Aerosol MBb
32
16
18
39
27
Aerosol MBb
38
11
32
56
1
Aerosol Non-MB'.'
74
24
76
0
0
tor
-
20p
'Measurements made with a Malvern ST 1800 a n a l y z e r , a t 90' 16" (406 mm) from the a c t u a t o r . Run i n d u p l i c a t e .
20p
-
sop
Over 5 0 ~
t o spray a x i s and
bThese a r e produced o u t s i d e the U.S
'The l a r g e amount of (CFC-11/12) propellant used i n t h i s product r e f l e c t s the high c o s t of ethanol i n the country where i t is produced: the "alcohol tax" cannot be avoided, a s i n the U.S.. f o r approved uses.
334 Alternative Formulations and Packaging to Reduce Use of CFCs
aerosol, by increasing the level of film-forming resin in the hair product formulation.
Some characteristics of pump-sprays are more economically attractive than aerosols.
For example, a plain glass cologne bottle, is less costly than a
heavier-walled, pressure-tested and PVC "Lamisol"-coated glass-in-plastic aerosol bottle.
The plain bottle also has a number of other advantages
relating to design flexibility. The filling operation for pumps is a single stage operation: the aerosols, however. must be filled and then gassed, requiring at least two stages.
They must also be hot-tanked.
Aerosol containers larger than 4 fluid ounces (118.3 mL) are restricted to cylinders of aluminum or steel, at least in the U.S.: whereas, finger-pump dispensers may be made of various plastic or glass containers and be attractively shaped. Unlike aerosols, they are not limited to 819.4 mL in size, although very few are more than about 12 fluid ounces (355 mL), for practical reasons. The flammability of aerosols and finger-pumps is commensurate in several ways.
Formulas for boch systems may range from 0% to 100% of flammable
components.
They pose approximately equal levels of hazard if exposed to an
ongoing fire in a warehouse.
The finger-pump can produce a flame volume of
from 0.8 to 1.6 U.S. Gallons (3,000 to 6.000 mL) per actuation if the contents are hair spray or bug killer, which contain essentially 100% flammable ingredients. The aerosol is similar, but the flame volume may be two or three times larger and may be sustained by merely keeping the button depressed. Aerosols can rupture if overheated, and if a flame source is present, they may generate a fireball up to 9 feet ( 2 . 7 m) in diameter. Typical products that have been successfully marketed in finger-pump sprayers include following: Bug Killers (such as ant. roach, spider, and bee killers)
Weed Killers Pet Sprays (often for insecticidal or grooming purposes)
Description of Aerosol Packaging Alternatives
335
Colognes and Perfumes Hair Sprays Hair bisturizers Curl Activators L ~ MCleaners (such as anti-fog and anti-static types)
Vermouth (for dry martinis) Germicides (including those for pre-operation washing) Spot Cleaners Pre-suntanning Accelerator Facial Rinse Cookare Lubricant Contact Lens Rinsing Sprays (requires Thimerisol or other disinfectant) Window Cleaners Topical Sprays (such as benzocaine or rubifacient types) Silver Polish Sprays Throat Sprays Leaf Shine Sprays Chrome Polishing Sprays (automotive uses) Stainless Steel Cleaners Uildevcides One disadvantage of finger-sprays not yet discussed is that all models KO varying degrees produce extremely coarse dribbles at the very beginning and the very end of each actuation. These heavy droplets fall downward very fast spotting po1ished;wood furniture, window sills, flat glass surfaces and some textiles, also cooling or wetting the skin avay from the sprayed area of the body.
Finger-pump sprays are usually not used with a number of product types such as the following: Volatile flammables
(such as cigarette lighter fluids)
Viscous liquids
(spray extra coarse, or may n o t spray)
336 Alternative Formulations and Packaging to Reduce Use of CFCs
Strong solvents
(such as nail polish removers & insect repellents)
Sterile liquids
(sterility is lost at the first actuation)
Acidic liquid
(acetal valve components dissolve below pH
-
3.6) ktOiStUe-S8MitiVe
(moisture enters by return air and permeation)
liquids Suspensoid fluids
(valve plugging can readily occur)
Foam-type emulsions
(foaming will not occur to any extent)
Polyethylene warping
(such as oleic acid or some block polymers)
liquids Staining liquids
(such as food colors, dyes, etc. because of dribble)
Sensitive liquids Two-phased liquids
(such as those harmed by air or light) (phases will reform in valve chamber and be resistant to reconstitution by shaking)
High-odor liquids
(garlic concentrates, etc. will permeare)
(In plastic bottles) In spite of all these apparent limitations, the finger-pump sprays e n j o y a business volume exceeding one billion units a year and remain the major competitor to aerosols.
Description of Aerosol Packaging Alternatives
337
Soraverg The sprayer is one form of the trigger-pump; the others extrude pastes,
g e l s . or liquid products. Trigger-pump sprayers are more costly than fingerpump sprayers; they are used with sopawhat larger dispensers, and more emphasis is given to refill units. The trigger mechanism facilitates the dispensing of larger quantities of product per shot, and the mechanical advantage or leverage feature of the pinioned trigger itself provides higher internal pressure in the chamber.
They are generally viewed as more utili-
tarian than discretionary; for example, there are few if any trigger type pup-action hair sprays.
(However. trigger pump lotions and cosmetic pastes
are aesthetic and quite popular.) Host trigger sprays are used for cleaning purposes, such as pre-laundry spot cleaners, disinfectant cleaners for hard surfaces, carpet cleaners, window cleaners. automotive cleaner and wax. vinyl top cleaners, induscrial lubricant cleaners, and concrete floor (grease and oil) cleaners.
Container
sizes of up to one U . S . Gallon (3,784 mL) are available for institutional uses. The operational principles, compatibility characteristics, and most other properties of the trigger-pump sprayers are equivalent to those of the smaller finger-pump sprayers and need not be repeated here. Fineer-Pumr, Extruders A minor modification of the actuator changes the finger-pump sprayer into an extruder suitable for dispensing lotions. creams ointments, gels. pastes, viscous liquids. and measured amounts of various concentrates for dilution with fixed amounts of water.
The actuator is removed and replaced with a
spout with a very narrow tubular exit pipe.
The small amount discharged per
shot makes it useful for costly pharmaceutical, skin dewrinklers, perfumed lotions and similar products. softener are sold in this form.
In Europe, a vitamin mixture and an ear-wax A concentrated cypermethrin and K-methrin
mixture that is dripped onto an absorbent wafer measuring about 17 X 45 X 2 rnm
338 Alternative Formulations and Packaging to Reduce Use of CFCs
in size is also sold in this form.
The treated wafer is slipped into a small
holder that plugs into a wall socket vhich gently heats it to vaporize the insecticidal additives.
The active ingredients are not volatilized in
sufficient concencratiolu to be lethal, but they are so irritating to mosquitoes that they vacate the room if possible.
The repellent action lasts 8
to 10 hours, ensuring people a good night’s sleep.
Most of the sales are in
Mediterranean countries, where the product has made serious inroads into the much more costly aerosol insecticide business.
Various modifications can be made to the trigger-pump sprayer to change it to a device with a spout able to dispense lotions, gels, and similar products in the form of a streau or ribbon.
Simplified and lover-cost
versions are also in demand that are used to discharge relatively large, fixed volumes of dishwashing detergents, fabric softeners, and other cleaners.
They
will have almost no effect on the aerosol market as possible alternatives and are not discussed further. DISPENSING CLOSURES One of the simplest possible designs is the screw-threaded closure or cap with a dispensing hole able to be plugged shut by various means.
Three of
these designs are illustrated in Figure 8. To operate these, the dispenser is held inverted to get the product near
the orifice. after which. the “F”-style metal can (oblong, with large front and back flat surfaces) or flexible plastic container is squeezed, expelling a stream or ribbon of the product.
Dispensers come in sizes of 6 to 64 fluid
ounces (177 to 1.892 mL) and can conveniently dispense liquids, thin gels, soft creams, and lotions, as long as they are flowable.
These containers are
used for charcoal lighters, various cosmetics. toiletries, personal care products, paint solvents, paint strippers and furniture polishes.
Description of Aerosol Packaging Alternatives
339
CAP OeK\
DISC
TOP -
OECU
BOOY
F l p r e 8.
Various Dispensing Closures-Kade by the Seaquist Closures Division
340 Alternative Formulations and Packaging to Reduce Use of CFCs
In addition to the designs illustrated above, there are turret spouts (truncated cone profile), lever spouts--in which a small pinioned plastic section is rotated 90' upward to operate the closure--and several related forms.
They are increasingly used instead of the simple, detachable screw-cap
dispensers.
Uses include certain foods (such as oleomargarine pourables.
ketchup, and mustard). lubricants, silicone shoe and boot dressing, some medicinals. and solvents for home w e . artists, and fndwtry. These products are major competitors with aerosols in the lubricant field (aerosol volume 95,000,000 units in 1988), for carburetor and choke cleaners (aerosols 57,000,000). waxes and polishes (aerosols 129,000,000), and certain other overlap product areas.
Since the closure is a single polyethylene
molded unit, generally applied semi-automatically as a replacement for screwthreads, it is a very economical option.
Some models can be made child
resistant. PRESSURIZING DISPENSERS Twist-N-Mist Over the years, several firms have developed various pressurized packaging systems quite different from the conventional aerosol form.
They invar-
iably use air pressure, the restorative pressure from an expanded rubber bladder, or some similar arrangement as the dispensing method.
They are
characterized by delivering either very coarse sprays or various lotions and semi-solid products, usually one or the other. The Twist-N-Mist 11 is a development of the CIDCO Group, Inc. of Denver, CO. which holds several U.S. Patents that cover the principles of the device, as well as those employed in related dispensers:
Pull-N-Mist and Dial-A-
Spray, details of which are still experimental and have not yet been released. The firm also holds several foreign pacents.
As in all such products, energy must be imparted to the dispenser to taka the place of the propellant gases used in aerosol forms.
For Twisc-N-Hisr 1 1 .
Description of Aerosol Packaging Alternatives
341
that energy is supplied manually, by rotating the full-diameter screw-cap and integral piston. The current model of Twist-N-Mist 11, of which several hundred have been made, uses a three-component outer s h e l l assembly, uhich measures about 2 3 / 4 "
X
6 1/2'
(70
X 165 mn) and consists of an HDPE threaded base, threaded top,
and matching body, as shown in Figure 9.
By turning (misting) the threaded cap several revolutions the incegral piston in the base of the cap io raised about 1/2 inch (12.7 mm) or so, creating a vacuum in the cylinder (reservoir) below. to
This causes the product
rise up the dip tube, past the stainless steel ball check valve, to fill
the cavity.
Enough is drawn up to provide a 7 - to 20-second spray time,
depending on the valve orifice. The cap is now twisted an equal number of turns in the opposite direction. forcing t h e integral piston dounuard until it hits against the base of the reservoir.
This action causes pressure to develop in the reservoir and
forces the trapped product downward into a Buna-N rubber bladder, which expands accordingly.
The memory of the elastomer causes pressure, which
decreases to some extent as the product is dispensed through an aerosol type valve, allouing the bladder to slowly regain its original "test-tube-like" profile.
The process must be repeated for another actuation.
The dimensional
changes in the unit during the suction and pressurization stages are shoun in Figure 10. As a fail-safe feature, the contents of the pressurized rubber bladder
will very slowly bleed back past the check valve barrier and into the main product storage compartment.
The bleed-back time can be controlled by varying
the surface finish of the check ball or check ball receptacle, or, if the product is viscous, by grooving the ball. A number of ocher features are possible.
The amount of pressurized
product (and thus spray time) can be pre-engineering by proper sizing of the reservoir, bladder and/or nozzle orifice.
The main section of the dispenser
342
Alternative Formulations and Packaging to Reduce Use of CFCS
Actuator button ' (HDPE) Twist cap (HDPE)
Check ball (stainless steel)
Dip tube (HDPE)
Figure 9
FfLLIBC UESEPVOIB Turning cap t o cha up position opth. rerorrroir d fills it chrm@ auction on the dip cub.
Figure 10.
DISPEHSING SWIILBCE -tine cap back t o chm dara position forcer the prducc f r a tmsarroir t o bl.ddar. Pres.* accucor dirchrrgms conC.Ptr.
Suction and Pressurization Stages of the Twist-N-Mist I1 Dispenser
Description of Aerosol Packaging Alternatives
ma&
343
from injecting blow-molded HDPE or HDPP, can be contoured to a modest
degree inward, outvard. or both, if the screw-threaded top and bottom sections remain round.
Technically, the dispenser can be provided with an integral
bottom at a slight decrease in cost, but this would make it into a one-time service unit, instead of a reusable type and increase cost-per-ounce (cost per
d.) significantly. This option is not generally recomnended. Because the upper cavities are completely filled with product, the unit nay be used with the dispenser held in any direction. of the contents.
It delivers about 95+%
Corrosion is not a problem, since the only metal parts are a
stainless steel spring and ball.
Stress cracking has been noted as a problem
with early single cavity models, mainly affecting the screw-threaded dome section and allowing leakage of the product.
If refined models are resistanc
to stress cracking, they should be tested with surfactant (as non-ionic) water
solutions that can often induce this problem in polyethylenes that are not formulated properly. The CIDCO Croup, Inc. recites the shortcomings of aerosols (their major target) as well as of finger-pumps and trigger-pumps, claiming that their dispenser, while somewhat costly to buy the first time, has long-range advantages, especially if refilled. However, several turns may be necessary to pull product from the main chamber and then force it into the Buna-N Rubber bladder against the back pressure from that diaphragm.
The spray duration could cease in the middle of
a spray episode, requiring the user to delay completion for an estimated 15 to 30 seconds to recharge the can.
The spray is much coarser than that o f
aerosol sprays, except for nitrosols.
No foams can be produced.
that have a profound swelling or deleterious effect upon the BUM-N can be used. except perhaps at low concentrations.
No solvencs
bladder
Product darkness o r odors
may develop unless the rubber bladder is specially lined, as in the Exxel system discussed below.
344 Alternative Formulations and Packaging to Reduce Use of CFCs
Briefly, this is another dispenser option vhere the product is contained in a thick. squeezable rubber sleeve open at one end, but in this case all the product is compressed into the inner container by a manufacturer or packager. The dispenser has aerosol properties, in that the product is always under pressure.
However. there are differences.
Sprays are propellant-free, and
therefore very coarse or vet, and no foam type products can be provided except for post-foaming gel types. The following steps are required to manufacture the Exxel System dispenser: Stretch-blov a biaxially oriented, thin-valled polyethylene teraphthalate (PET) bottle: Form longitudinal pleats in the bottle, using patented equipment: Apply a double layer of barrier sealant and liquid latex to the bottle; Insert a customized valve and clinch in place at the top ring of the bottle; Insert bottle into a rubber sleeve: Place container into a suitable outer container and attach at the top; and Force a predetermined amount of product into inner container v i a the valve.
Description of Aerosol Packaging Alternatives
345
Construction materials that can contact products are limited to the PET bottle, the Nylon 66 valve housing, natural polypropylene, the HDPE button, and either the SS a302 or #316 spring. PET/valve gasket must be mentioned.
An insignificant exposure to the
The gasket is available in various
materials. A sampling
of products currently being packed in the Exxel system appears
in Table 47. Exxel comments that skin care, hair care, and pharmaceutical products o f the post-forming gel type are well along in the development stages. A l s o , several medicinal ointments are under intensive study by Upjohn and others. Cost comparisons can be made with other forms of packaging, using the tabulated data in Table 4 8 .
The Exxel system is incompatible, to varying degrees, with certain formulations.
Following is a lisc of ingredients and characteristics that
would make a product incompatible with the Exxel system: Certain polymer solvents--terpenes, ketones, etc.; pH Values over 10.0; Isopropanol, above 5.0%: Prolonged exposures to over 113'F
(45'C);
Particulate matter--since effective shake-before-use High surface tension breakup products; Resins with an ability to dry and clog actuators;
3
impossi Le:
Alternative Formulations and Packaging to Reduce Use of CFCs
346
TABLE 47. TYPICAL CURRENT CUSTOMERS AND PRODUCTS OF THE EXXEL SYSTEM C0nP-Y
Product
Air Products and Chemicals Company
Welding Flux Spray
Chanel, Inc.
S u n Oil Spary
Kobayashi Pharmaceuticals Coopmy
Muscle Relaxant
Nihon Sanro. Ltd.
Pure Food Products
Prudue Frederich. Inc.
"Betadyne" Solution.
P . R . Hertensen
"Citruscent" Fragrance
Tokyo Aerosol Co.
Hair Gel
Wella
Shampoo and Conditioner
J er gens
Topical Lotionsb
Uestvood Pharmaceuticals, .Inc.
"Alpha Keri" Spray Oil
Adrien Arpel
"Aronafleur" Flower Extract Foam Firming Masque
Estee Lauder, Ltd.
Hair Reviving Mist
HiLo Products
"Silent Force" Flea Spray
Laboratoires Goemar, S.A. (France)
"Tonialg" "Tonialg" "Tonialg" "Tonialg" "Tonialg" "Tonialg" "Tonialg" "Tonialg" "Tonialg" "Tonialg"
'Tamed Iodine formulation. bAs
of 1988.
-
sterile
Restorative Conditioner Toning Lotion Night Creme Restorative Shampoo Hand 6 Body Creme Bath & Shower Gel Foaming Bath Cleanser Nourishing Creme Body Contouring Creme
Description of Aerosol Packaging Alternatives
TA
E 48.
ST
F W
-
L SYSTEM PACKAGING AND FILLING SERVICES (VOLUME
lMM)
16
16
241
274
Accuator
30
30
Overcap
22
22
Decorated Bottle
85
95
UQ
140
5 34
577
Snap Ring
Power Assembly Unit
Filling Charge (Contract)
NOTE:
347
Add $lot4 for 500,000 quantities and $20U for 250,000 quantities. Add $25/M for pre-fill electron beam sterilization.
TABLE 4 9 .
MINIMM DIMENSIONS OF OUTER CONTAINERS FOR EXXEL UNITS
Dimension Minimum length. Top of neck finish to inside of bottom. Minimum width'. dimension.
Note:
Internal .
4
02.
Size
7
02.
Size
5.450 in. (138 m)
7.300 in. (185 nan)
2.223 in. ( 5 6 . 5 ram)
2.223 in. (56.5 mm)
Intentionally undarfillad -el units will permit the use of outer containers with reduced minimum internal widths. Outer containers require a vent hole of at least 0.015" ( 0 . 3 8 mm). preferably in the base, but alternatively in the shoulder.
348 Alternative Formulations and Packaging to Reduce Use of CFCs
Formulas that require in-package mixing, e.g., bi-phasics; and Ethanol, above 60%--should be carefully tested for compatibility. The outer container may be made from glass, plastic metal, composites, For automated filling, the con-
paper, or (theoretically) nothing at all.
tainer should be able to support a hold-dom filling force of 25 pounds (11.4 kg) without buckling.
To accommodate the two Exxel System inner containers,
the minimum internal dimensions of the outer containers must be considered, as shown in Table 49. The smaller (4-fl.oz.) Exxel package will deliver 92 to 95% of its contents before fully depressurizing.
The 'I-f1.02. size will deliver 92 to
84.7%. These ranges are reduced to 90 to 93% in the case of fairly viscous
items with positive yield points.
After about 86 to 88% of spray products
have been dispensed, the bag pressure falls below about 17.5 psig (1.23 bar) and the spray pattern deteriorates rapidly.
The pressure at which this occurs
depends on the ingredients and the viscosity of the formulation.
As a rule,
storage weight loss will be 1.0% per year at ambient temperature or per month at 104'F
(4O'C).
The Exxel System is self-pressurized and may be classed as an aerosol under the DOT shipping regulations; however, DOT Exemption No. E-9607 has been obtained by the Darvorth Company (Div. of Ensign-Bickford, Inc.) to set aside these requirements for hot tanking, etc.
This now applies to all Exxel System
products.
The Mistlon Eco-Logical Spray Bottle is a dispenser developed in Japan, made in South Korea, and offered for sale by the MONDEX Trade C Development Corporation, 2 St. Clair Avenue
-
West (Suite 801), Toronto H4V L I S , Canada.
It is cylindrical and measures 2 1/8" X 8 1/2" high (54 X 216 mm). wholesale price is about $1.00,
The
Description of Aerosol Packaging Alternatives
349
To use the empty unit, the full-diameter polypropylene cap is removed, after vhich a screw-threaded closure carrying an ordinary aerosol valve and A quantity of product is poured into the bottle
actuator is also removed.
through the one-inch ( 2 5 . 4 ma) opening.
A typical fill i s 250 mL.
After
this, the closure is screwed back into place, allowing a thin rubber "0"-ring to make a reliable hermetic seal. (25.4
mp)]
The base section [full-diameter and 1" high
is nov withdrawn. away from the rest of the unit, exposing a hollow
cylinder 11/16" in diameter by 3 11/16" long (17.5 X 93.7 mm), fitted with a one-way compound valve.
The hollow cylinder functions as a piston, within a
cylinder protruding up.ward into the container, also ending in a one-way valve.
To pressurize the air in the container, the base section is pumped a number of times.
By pressing a soft diaphragm in the center of the base, excess air
pressure within the hollow cylinder is removed, allowing it to fit snugly against the bottom-most area of the body as before. The unit is equipped with either a 0.010" ( 0 . 2 5 mm) or 0 . 0 1 4 " (0.36 mm) mechanical breakup bottom.
In the case of uater. these actuators will provide The
an acceptable spray if the air pressure is 18 psig (1.17 bar) or greater. operating characteristics follow simple gas laws.
This can be illustrated by
the following example. Characteristics: The head space volume is 100 mL. The liquid volume is immaterial. The applied pressure is 50 psig (3.52 bar) Question:
How much product can be dispensed before the pressure sinks to 18 psig (1.17 bar) and the spray starts to deteriorate?
350 Alternative Formulations and Packaging to Reduce Use of CFCs
Solution:
--
Convert to absolute pressures.
50 psig 18 psig
6 4 . 7 psi-abs ( 4 . 5 6 bars
32.7 psi-abs (2.30 bars
-
absolute) absolute)
Boyle's Law:
V, V,
-
V (P /PI)
-
100 PL X ( 6 4 . 7 / 3 2 . 7 )
1 9 7 . 9 PL
Change in head space volume.
V,
-
V,
-
V
-
197.9
-
100.0
-
9 7 . 9 I&.
Answer : 9 7 . 9 mL of liquid can be dispensed before the spray deteriorates.
It follows that, the larger the head space, the more strokes of the
piston will be needed to pressurize to a given level, and the more liquid can be dispensed as a result. With some degree of manual difficulty, the Kistlon unit can be pressurized to 65 psig ( 4 . 5 8 bars). pressure.
There vas no evidence of deformation at this
The unit might be pressurizable to well over 100 psig (7.04 bars)
without any problems-unless it is strongly heated to the point where the polypropylene begins to soften and become deformable. The delivery rate will, of course, vary with the container pressure. With the 0.014" (0.36-mm) MB valve button, water delivers at about 0.5 g/s at 20 psig (1.41 bar) and about 0 . 7 2 g / s at 40 psig ( 2 . 8 2 bar).
Like the Twist-N-Mist dispenser, the unit is limited in terms of spray Highly flammable
particle size and range of products that can be dispensed.
Description of Aerosol Packaging Alternatives
351
materials, those that deform polypropylene or attack polyvinylacetate, and viscous fluids are among those that should not be used.
The unit cannot be
used to generate a direct foam, but with a suitable straight bore actuator it could direct a thin stream into the palm that would then spring into a foam.
This product, which is similar to the Nistlon dispenser also uses a pumping action to compress air into the pressure-resistant container. When reasonably full, it must be pumped 10 to 20 times to create an effective spray that does not quickly deteriorate as pressure drops. As the container empties. the number of pumping strokes must be increased, but the pressure Lasts longer during dispensing.
The unit must be-held upright to keep the
diptutie below the liquid surface, but if the container is held so that the compressed air is unloaded, it can be quickly pumped up again, unlike aerosol products with nitrogen or other propellants in l o v concentrations. The cylinder is cylindrical to withstand the generated air pressures without buckling or other deformations. Comments made about the Kistlon dispenser apply here as well. Invented in Sweden. the Airspray system vas developed and refined by a Dutch company, which marketed the unit in Europe for several years.
In 1987
they entered into an agreement with the National Can Corporation, which is now a part of the American National Can Company unit of Pechiney, S.A., to manufacture and market the system in the U.S. under license.
As of 1989, the
system will be jointly marketed in the U.S. by Airspray International, Inc. (Pompano Beach, FL) and American National Can Company (Chicago, IL). It is promoted in Canada by U. Braun C Company (Harkham. Ontario WR 3B3, Canada). The system is offered in tvo versions: with a refillable screw top and a It can be made in containers of plastic, metal, or
disposable crimp-on. glass. plastic.
PET containers are being developed at this time. All the parts are Once pressurized to 55 psig (3.87 bars)--the recommended maximum--it
will dispense up to 100 mL before repumping is needed.
Airspray supplies an
Alternative Formulations and Packaging to Reduce Use of CFCs
352
O.T.I.
crimping machine f o r c l o s i n g and p r e s s u r i z i n g the system a t 1500 p/hr
with compressed a i r . W e r d i n p v - S v s t w A v a r i e t y of i n t e r - r e l a t e d systems have been developed by Werdi Spray, S.A. 5 , Route des Jeunes, CH-1227 Geneva (Switzerl-and).
They a r e represented
i n t h e U.S. by Werding Aerosol Technology I n c . , U.S., located a t 4978 Kingsway, Burnaby, B r i t i s h Columbia V5H 2E4, Canada. The firm makes both non-aerosol containers and t h e i r unique Werdi ' R ' Actuator.
The l a t t e r can be designed t o provide a constant d e l i v e r y r a t e ,
regardless of the i n t e r n a l pressure of the dispenser, and is thus most u s e f u l f o r products pressurized v i t h a i r , nitrogen, carbon dioxide, e t c . , where pressure drops during use can exceed 70%. The Werdi 'R' System comprises the Werdi 'R' Actuator ( f i t t e d with the Werdi 'N' Nozzle and t h r u s t r e g u l a t o r ) and the Werdi Valve.
For l o t i o n s and creams, the Werdi 'RD' system is suggested,
vhich c o n s i s t s of the Werdi 'RD' Actuator ( f i t t e d with t h e t h r u s t r e g u l a t o r and a s e l f - c l o s i n g d i f f u s o r ) and the Werdi Valve. The Werdi 'N' Nozzle achieves a high mechanical breakup e f f e c t by means of its multi-staged, interconnected Venturi system, and thus c o n t r i b u t e s more t o spray breakup than conventional ( l e s s c o s t l y ) mechanical breakup actuacors. F i t t e d behind the nozzle i n the a c t u a t o r , the t h r u s t regulator c o n t r o l s the flow of product t o the nozzle.
The patented design includes two s t a i n l e s s
s t e e l a c c e l e r a t o r d i s c s and a p l a s t i c expansion chamber as w e l l a s a s p e c i a l r e g u l a t i o n d i s c , which is c u t , curved. and formed t o exacting standards.
The r e g u l a t i o n d i s c is compressed by higher pressures, but because of the spring e f f e c t of the metal, t h i s opens the c u t and increases the o r i f i c e s i z e as the pressure drops.
Turbulence i n t e n t i o n a l l y c r e a t e d by the design of the
companion d i s c s , as v e l 1 as the nozzle i t s e l f . produces a r e s i s t a n c e t o the product flow i n t o the t h r u s t r e g u l a t o r , whose force is d i r e c t l y proportional t o the pressure.
The higher the pressure, the more these turbulent e f f e c t s
Description of Aerosol Packaging Alternatives
brake the d e l i v e r y r a t e .
Thus, the Werdi
353
'R' Actuator maintains a constant
outflow of product from t h e container. There a r e f o u r types of the Werdi 'N' f e r e n t spray rates and p a t t e r n s .
Nozzle. which a r e used f o r d i f -
When a nonaerosol ( o r a e r o s o l ) container is
f i l l e d t o 65 volume percent with low-viscosity concentrate and then p r e s s u r i z e d w i t h air o r nitrogen t o 85 p s i g ( 6 b a r s ) , the r e s u l t s a r e as shown i n Table 5 0 . Werdf a l s o makes complete valves as w e l l as nonaerosol (pump-type) c o n t a i n e r s , b u t t h e i r primary c o n t r i b u t i o n t o nonaerosol dispenser technology appears t o be i n the a c t u a t o r a r e a . .The following U . S . Patents a r e reference sources:
4.487,554 (11-DEC-84). 4,260,110 (7-APR-81).and B a t t e l l e ' s
4,603.794 ( 5 AUG-86).
The last describes a dispenser a b l e t o d e l i v e r a high-
pressure spray by means of a low-pressure squeeze on the f l e x i b l e sidewall a r e a , following a pressure multiplying p r i n c i p l e . Latest r e p o r t s suggest t h a t a l a r g e Northern I t a l i a n watchmaking firm is i n t e r e s t e d i n purchasing Werdi because they have f a c i l i t i e s t o produce many o f the very small a c t u a t o r and o t h e r p a r t s required f o r the system. MISCELLANEOUS AEROSOL ALTERNATIVES A number of dispensers can be used t o present products t h a t compete with
the aerosol system, although they may bear no d i r e c t s i m i l a r i t y t o a e r o s o l s . Two w i l l be considered i n the following pages. J n s e c t i c i d e Vauorizers
Vaporizers of various types have been used t o provide " t r u e aerosol" m i s t s o r condensation nuclei of products i n the a i r .
For the most p a r t , they
have been used f o r i n s e c t i c i d e s , but t r i e t h y l e n e glycol m i s t s of hexylresorc i n o l and o t h e r h e a l t h - r e l a t e d products have enjoyed a much smaller market.
354
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 50. SPECIFICATIONS--USING FOUR NOZZLES--FOR THE WEFLDI 'R' ACTUATOR
Nozzle
Type A
Type B
Type C
Type D
Color Coda
White
Yellow
Green
Black
Average Delivery Rate (mL/sec. )
0.70
0.67
1.30
1.30
Aver age particle Sire (microns)
3.
5.
Cone Angle of Spray Pattern
50'
30'
40 =
30'
Cone Length ( inches)
,30
26
55
36
Range of Applications
0.7
-
3'
25
-
50
Personal Deodorants
Hair Spray
Space Insecticide
Polishes
Pre-shaves
Wound Spray
Air Fresheners
Surface Insecticide
Leaf Polish Hold Re leases
Surface Disinfectants
'The average particle size for Types A, B. and C appear to be unusually low for air sprays.
Description of Aerosol Packaging Alternatives
355
In Latin America, Spain, Portugal, Tripoli, and other areas the electrically vaporized insecticide products form the largest single use for insecticide applications.
Individual insecticide wafer sales volumes are greater
than rhe total aerosol markets in these countries.
Such well-known firms as
S.C. Johnson 6 Son, Inc.. Refinacoes de Milho, Brasil, Ltda (STP Brands), Bayer, GmbH (BAYGON Brands). and Reckett 6 Coleman, Ltd. (Various Brands) sell the wafers. The vafer, which containa a few drops of absorbed insecticide concentrate, is placed in a holder on the heater, which is then connected to a wall plug of electric current. The wafer is gently warmed to release the insecticide materials.
Although nontoxic at low levels of use, the insecti-
cides irritate mosquitoes (and "permi1ongos"--long-legged mosquitoes) so that they leave the room.
Especially useful in sleeping quarters, the wafer has
useful service life of from eight to ten hours.
Foil packs of these products
are now being replaced vith PET-laminate packs to reduce packaging costs.
Coming into major use only about ten years ago, the stick-in-canister option has become the leading alternative for antiperspirants and personal deodorants.
A much smaller market exists for other items such as stick i n s e c t
repellents, stick spot-cleaners for textiles, stick analgesics (methyl salicylate types, for example), and several other products. Several types of polyethylene and polypropylene round and oval canisters exist. The most popular are in the 1.5- to 3 . 5 - Av.02. ( 4 2 . 5 to 9 9 . 2 g) size, with a bottom-entering plastic screv that, when rotated, elevates the product so that it protrudes sufficiently from the top of che canister to allow for
convenient use. A ty-pical stick antiperspirant formulation contains 20 to 2 5 % of the aluminum chlorohydrate complex salt, compared with 7 to 12.5% in aerosol products.
Two representative formulas appear in Table 51.
356 Alternative Formulations and Packaging to Reduce Use of CFCs
- TABLE 5 1 .
TWO STICK ANTIPERSPIRANT FORMULAS
Improved Antiperspirant Stick Formula
Antiperspirant Stick
I
(A) Cyclimathicone
PhaPc4
Permethyl 99A' Isododecane Permethyl 10lA' Isohexadecane DOW Corning 2 u b cyclome thicone Fluid A/PcPPG-14 Butyl Ether
-
Crodacol S - 9 5 c Stearyl Alcohol Cas torwax W -80d Hydrogenated Castor Oil
Micro-Ace P-2' Talc
ElzSLD
Spheron P-1500' Silica
4.00
13.15 11.50
Stearyl Alcohol PPG-15 Stearyl Ether (ARLAnOL E) (IC1 Specialty Chemicals) (B) Hydrogenated Castor Oil
11.50
Stearath-20 (BRIJ 78) (IC1 Specialty Chemicals)
10.50 2.00
22.00
Manufacturine Procedurc: Add Phase A in order to vessel, heat to 7075°C. nix until clear and uniform. While mixing, add Phase B one item at a time. Continue mixing until clear and uniform. Maintain 70 to 75'C. add Phase C, keep agitation vigorous. Add Phase D, mix for 5 10 minutes. Pour into containers at 66-68'C.
Suppliers: 'Presperse Inc. bDov Corning 'Croda dCas Chem .Reheis
23.0 5.0
2.0 1.0
7.50
!hz!cz
Micro Dry. Aluminum Chlorohydrate
43.5
17.15
(C) Silica
w
-%
Aluminum Chlorohydrate
0.5
25.0
procedure: Heat (B) to approximately 65'C until liquid. Add (A) with moderate agitation and heat to minimize silicone evaporation. Add (C) and stir 5-10 minutes until uniform. Cool to 55'C with stirring and pour into stick forms.
Description of Aerosol Packaging Alternatives
357
All significant marketers of aerosol underarm products also sell the Each line generally has two sizes and "scented" and
stick products.
"unscented" versions.
Product effectiveness is equivalent to, or somewhat
higher than, those of the latest generation of aerosols, and the "antiperspirancy" of both versions is well above FDA requirements. The antiperspirant type of underam product commands 81% of the total underarm aerosol business, and 83% of the stick alternative. The personal deodorant subsegment is presented in the same container types and sizes. Instead of aluminum astringent salt, it contains 0.1 to 0.2% of a germicidal material, typically Triclosan, a diphenyl derivative made by Ciba-Geigy Corporation.
Table 52 shows approximace production volumes of aerosol and
stick underarm products. Other packaging forms, including roll-ono and pads, make up a relatively minor proportion of the U.S. market.
These secondary alternates will not be
covered here. Aerosol and stick underarm products are mature markets.
The change in
ratio shown in Table 52 is the result of new antiperspirant entrants (BristolMyers and Hennen) whose advertising helped both their products and the aerosol packaging concept.
In addition. reformulation to more powerful forms of the
aluminum chlorohydrate have made aerosol antiperspirants more effective. Unless significant changes in price structure, ecological aspects, flammability considerations, or other criteria affect one product at the expense of the other, the 1:1.50 ratio of aerosols to sticks will probably continue for a long time. years.
No dramatic changes are seen in this ratio for at least four
358
Alternative Formulations and Packaging to Reduce Use of CFCs
TABLE 52.
PRODUCTION UNITS OF UNDERARM PRODUCTS ( U . S . )
Year
Aerosols
Sticks
Rario
1986
153,000,000
256,000.000
1:1.69
1987
164,500,000
278.000,000
1:1.69
1988
193,000,000
292,000,000
1:1.51
1989.
207,000,000
3io,oo~,oao
1:1.49
'Estimated figures a t mid-1989.
3. Summary Part I of this report discusses the aerosol industry's experience in converting from CFC propellants to alternative aerosol formulations. Some of the U d i a t e l y available alternatives, such as HCFC-22 and 1.1.1trichloroethane, also can deplete stratospheric ozone levels, although their ozone depletion potentials are less than those of the CFC propellants. Such conpounds as HCFC-123. RCFC-124, HFC-125, HCFC-132b. HCFC-133a. HFC1 3 4 ~ .and HCFC-14lb are now undergoing extensive toxicological testing that vi11 continu until about 1992.
Many of these "future alternative" compounds
are nonflammable unless they are mixed w i t h substances such as iso-butane or ethanol; ochers are fl-ble.
Hydrocarbon propellants, which cost less than
CFCs, are often the propellants of choice unless special properties such as increased solvency or reduced flammability are needed. is the next most preferred CFC alternative.
Dimethyl ether ( M E )
DPIE is flammable and a strong
solvent. Carbon dioxide. nitrous oxide, and nitrogen are inexpensive and widely available throughout the world but have been underused as aerosol propellants. Special equipment is often needed to add then to the aerosol containers. As CFC suppliers in the U.S.. Western Europe, Japan, and other parts of the vorld develop their CFC phase-down programs, vhich vi11 go beyond the Montreal Protocol, they will be focussing on rapid commercialization and application of the HCFC and HFC alternatives. The major alternative will be HFC-134a. vhich will replace CFC-12 in refrigeration, freezant. and air conditioning systems.
359
360 Alternative Formulations and Packaging to Reduce Use of CFCs
A variety of alternative aerosol packaging forms has been discussed in Part 11. with a special focus on those most like regular aerosols in characteristics.
A l l the alternatives have subsidiary positions in the
marketplace, if the volume of each is compared with the 3,000,000,000-unit volume of aerosols.
Several have been available for many years but have not
significantly penetrated the market for several reasons, shown below: They generally cost more (finger-pumps and sticks are exceptions) They are limited in their product compatibility They depend on chemical or mechanical (often manual) action to generate pressures needed to discharge the contents. Products must be delivered as very coarse streams, pourables. paste ribbons or (sometimes) post-foaming gels
--
without having the broad
range of the aerosol presentation. Sterility is generally impossible. Sprays can deteriorate during use. Several are incompletely tested. Several require capital expenditures for special filling or gassing equipment. Sizes are limited to the 3-fl.oz. to 12-fl.oz. (119- to 355-mL) range (some are even more limited).
In general, the packaging alternatives continue to be niche-fillers. Sales volumes are expected co grov to some extent, however, taking some market share away from aerosols in selected areas, but vithout significantly affecting the aerosol business if working best f o r a very limited range of products.
the present
mix of political. regulatory, economic, environmental, financial,
and other issms r e M i M raroonably StatLC.
Appendix A-Metric
To Convert Form
Quant ty
LenGth: Area:
Volume : Mass (weight):
Pressure:
Temperature: Caloric Value: Enthalpy : Specific-Heat Capacity: Density: Concentration:
F1 owrate: Velocitv: Viscosity:
(SI) Conversion Factors To
in ft in’ ft’
Multiply By
cm m
2.54 0.3048 cm’ 6.4516 m’ 0.0929 in’ cm’ 16.39 ft’ to’ 0.0283 m’ 0.0038 gal lb kg 0.4536 02 kg 0.0283 short ton (ton) Mg 0.9072 0,9072 short ton (ton) metric ton (t) atm kPa 101.3 Hg kPa 0.133 wig kPa 6.895 Psig kPa’ ((psig)+14.696)~(6 895) T “C* (5/9)x(’F-32) “C K‘ ‘C+273.15 W/kg 2.326 Btu/lb Btu/l bmol kJ/kgmol 2.326 kcal/gmol k.J/kgmol 4.184 Btu/lb-”F kJ/kg ‘C 4.1868
-
1b/f t’ k/m’ lb/gal kg/m’ oz/gal quarts/gal cm’/m’ gal/min m’/min m’/dav gal/day ft’/min m’/min ft/min m/min centipoise (CP) Pa-s (kg/m-s)
‘Calculate as indicated
361
16.02 119.8 25.000 0.0038 0.0038 0.0283 0.3048 0.001